Download Estudio desde primeros principios de mecanismos de apantallado

Universidad de Cantabria Facultad de Ciencias Dpto. Ciencias de la Tierra y Física de la Materia Condensada Estudio desde primeros principios de mecanismos de apantallado del campo de depolarización en condensadores nanométricos. TESIS DOCTORAL Pablo Aguado Puente Universidad de Cantabria Facultad de Ciencias Dpto. de Ciencias de la Tierra y Fı́sica de la Materia Condensada First-principles study of screening mechanisms of the depolarizing field in nanosized capacitors Memoria presentada por Pablo Aguado Puente para optar al tı́tulo de Doctor por la Universidad de Cantabria Memoria dirigida por Dr. Javier Junquera Quintana Junio 2011 Dpto. Ciencias de la Tierra y Física de la Materia Condensada Facultad de Ciencias Avda. Los Castros, s/n. 39005 Santander D. Javier Junquera Quintana, Profesor Titular del departamento de Ciencias de la Tierra y Física de la Materia Condensada de la Universidad de Cantabria INFORMA: Que el trabajo presentado en esta memoria, titulado “Estudio desde primeros principios de mecanismos de apantallado del campo de depolarización en condensadores nanométricos.” ha sido realizado bajo su dirección por D. Pablo Aguado Puente en el Departamento de Ciencias de la Tierra y Física de la Materia Condensada de la Universidad de Cantabria y EMITE su conformidad para que dicha memoria sea presentada y tenga lugar, posteriormente, su correspondiente defensa para optar al título de Doctor por la Universidad de Cantabria. En Santander, a 21 de junio de 2011 Fdo.: Javier Junquera Quintana Mi agradecimiento Quiero darle las gracias a Javier por lo mucho que me ha enseñado en estos años, de ciencia y de lo que no es ciencia, por ponerme las cosas fáciles, por la confianza que siempre ha tenido en mı́ y por lo contagioso de su entusiasmo por lo que hace. En estos años he tenido la suerte de conocer y trabajar con mucha gente generosa y siempre dispuesta a colaborar. A Max Stengel, a cuyo continuo bombardeo de ideas debo una parte importante de esta tesis, más de tres años y veintisiete páginas de artı́culo después. To Philippe Ghosez, Eric Bousquet, Pavlo Zubko and Pablo Garcı́a for the enriching discussions and all the things I have learned from them. My sincere acknowledgement to Patrycja Paruch for her hospitality during my stay in Geneva and for showing me how a ferroelectric looks like in the real world. To the rest of the people at Geneva, I really enjoyed the time I spent there. To Karin Rabe for her kindness and valuable scientific advise during my stay at Rutgers. To Morrel Cohen for the, unfortunately few, but insightful discussions we had during my visit. A Fernando y los de altas presiones por acogerme como mascota. A Lucie que no sabe jugar a los dardos. A los del despacho, a la Jefa, a Trueba que nunca se queja, a Susana, a Rosa, a Marcos, a Diego, a Carlos, a Cristina y a Pincho. A Echeandı́a porque si no se le echarı́a de menos. A Elisa porque ella lo dejaba ası́, a la Matahierbas, a Kus y al Chopo. A Spirit que está de fiesta. A Trufa y a Coco. A los blogs. A la noche de hoy porque ya casi es de dı́a. A Calvin y a Hobbes. Al chocolate. A Alba. A mis padres por los legos y bizcochos y por su cariño. i Este trabajo de investigación ha sido realizado gracias a una beca FPU del Ministerio de Educación (Ref. AP2006-02958), que también ha cubierto las estancias en las Universidades de Ginebra (Suiza) y Rutgers (EE.UU.), ası́ como gracias a la financiación del Ministerio de Educación y Ciencia (Proyecto Ref. FIS2006-02261), del Ministerio de Ciencia e Innovación (Proyecto Ref. FIS2009-12721-C04-02) y el Séptimo programa Marco de la Unión Europea (Proyecto OxIDes: Oxides Interface Design). Los recursos computacionales han sido proporcionados por el grupo ATC de la Universidad de Cantabria y la Red Española de Supercomputación. Glossary AFD B1-WC BZ CBM CNL D DFT DOS E Ed EC ECNL EF EV ε ε0 ε∞ FE φn , φp φp GGA LDA LDOS λeff M MIGS Nx P PDOS VBM Z∗ Antiferrodistortive (mode) B1-Wu-Cohen approximation Brillouin zone Conduction band minimum Charge neutrality level Electric displacement field Density functional theory Density of states Electric field Depolarizing field Energy of the bottom of the conduction band Charge neutrality level Fermi energy Energy of the top of the valence band Relative permittivity Vacuum permittivity Electronic permittivity Strain Ferroelectric Schottky barrier for electrons Schottky barrier for holes Generalized gradient approximation Local density approximation Local density of states Effective screening length Metal Metal-induced gap states Domain structure periodicity Polarization Projected density of states Valence band maximum Born effective charge iii Contents Glossary iii Introduction 1 1 Ferroelectric thin films 1.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . 1.2 Ferroelectricity in bulk . . . . . . . . . . . . . . . . . 1.2.1 Soft modes and double well energy . . . . . . 1.2.2 Anomalous dynamical charges . . . . . . . . . 1.2.3 Origin of the ferroelectricity . . . . . . . . . . 1.2.4 Non-polar instabilities . . . . . . . . . . . . . 1.3 Ferroelectric thin films . . . . . . . . . . . . . . . . . 1.3.1 Mechanical boundary condition . . . . . . . . 1.3.2 Electrical boundary condition . . . . . . . . . 1.4 Convergence of experiments and theoretical methods 1.5 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 5 6 7 9 10 11 12 13 16 26 29 2 Methodology 2.1 Introduction . . . . . . . . . . . . . . . . . . . . . . 2.2 Overview of approximations . . . . . . . . . . . . . 2.3 Born-Oppenheimer approximation . . . . . . . . . 2.4 Density functional theory . . . . . . . . . . . . . . 2.4.1 Exchange and correlation functional . . . . 2.5 Pseudopotentials . . . . . . . . . . . . . . . . . . . 2.6 Periodic boundary conditions . . . . . . . . . . . . 2.7 Brillouin zone sampling and electronic temperature 2.8 Basis sets . . . . . . . . . . . . . . . . . . . . . . . 2.8.1 Plane waves . . . . . . . . . . . . . . . . . . 2.8.2 Atomic orbitals . . . . . . . . . . . . . . . . 2.8.3 Atomic spheres . . . . . . . . . . . . . . . . 2.9 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 31 31 33 33 36 37 38 41 43 43 44 45 45 v . . . . . . . . . . . . . vi Contents 3 Band alignment issues in the ab initio simulation of ferroelectric pacitors 3.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2 General theory of the band offset . . . . . . . . . . . . . . . . . . . . . 3.2.1 Schottky barriers at metal/insulator interfaces . . . . . . . . . 3.2.2 Theory of Schottky barriers in ferroelectric capacitors . . . . . 3.2.3 Ferroelectric capacitors in a pathological regime . . . . . . . . 3.2.4 Implications for the analysis of the ab-initio results . . . . . . . 3.3 Methods . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3.1 Schottky barriers from ab initio simulations . . . . . . . . . . . 3.3.2 Electrical analysis of the charge spill-out . . . . . . . . . . . . . 3.3.3 Constrained-D calculations . . . . . . . . . . . . . . . . . . . . 3.3.4 Computational parameters . . . . . . . . . . . . . . . . . . . . 3.4 Results: Non polar capacitors . . . . . . . . . . . . . . . . . . . . . . . 3.4.1 Non-pathological cases . . . . . . . . . . . . . . . . . . . . . . . 3.4.2 Pathological cases . . . . . . . . . . . . . . . . . . . . . . . . . 3.5 Results: Polar capacitors . . . . . . . . . . . . . . . . . . . . . . . . . . 3.5.1 Short-circuit calculations . . . . . . . . . . . . . . . . . . . . . 3.5.2 Open-circuit calculations . . . . . . . . . . . . . . . . . . . . . 3.6 Discussion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.6.1 Structural properties of the film . . . . . . . . . . . . . . . . . 3.6.2 Stability of the ferroelectric state . . . . . . . . . . . . . . . . . 3.6.3 Transport properties in the tunneling regime . . . . . . . . . . 3.6.4 Interface magnetoelectric effects . . . . . . . . . . . . . . . . . 3.6.5 Schottky barriers . . . . . . . . . . . . . . . . . . . . . . . . . . 3.7 Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 Metal-induced gap states in ferroelectric capacitors 4.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4.2 Metal-induced gap states and complex band structure . 4.2.1 Complex band structure: a simple example . . . 4.2.2 Connection with Schottky barriers . . . . . . . . 4.3 Computational details . . . . . . . . . . . . . . . . . . . 4.3.1 Compatibility tests . . . . . . . . . . . . . . . . . 4.4 Complex band structure of bulk PbTiO3 . . . . . . . . . 4.5 MIGS in ab initio simulations of ferroelectric capacitors 4.6 Discussion and perspectives . . . . . . . . . . . . . . . . ca. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 47 47 51 51 53 57 64 65 65 70 73 75 76 76 79 88 88 93 96 96 97 99 99 100 101 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 103 104 105 108 117 118 118 126 132 5 Ferromagnetic-like closure domains in ferroelectric capacitors 5.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5.2 System and computational details . . . . . . . . . . . . . . . . . 5.3 Structure of polarization domains in ferroelectric thin films . . . 5.4 Role of the electrodes on the formation of polarization domains . 5.5 Screening of the depolarizing field . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 135 135 136 137 142 146 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii 5.6 5.7 Theoretical prediction and experimental observation of closure domains in ferroelectric thin films . . . . . . . . . . . . . . . . . . . . . . . . . . . . 147 Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148 6 PbTiO3 /SrTiO3 superlattices 6.1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.2 Structure and computational details . . . . . . . . . . . . . . . . . . . . 6.3 Mixed ferroelectric-antiferrodistortive-strain coupling in the monodomain configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.3.1 Periodicity dependence of FE-AFD coupling . . . . . . . . . . . . 6.3.2 Emergence of an r-phase in PbTiO3 /SrTiO3 superlattices . . . . 6.3.3 Covalent model for the polarization-octahedra rotation coupling 6.3.4 Piezoelectric response of the system . . . . . . . . . . . . . . . . 6.4 Polydomain structures . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6.5 Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusions A Ocupation function and energy smearing of A.1 Convolutions . . . . . . . . . . . . . . . . . A.2 Local density of states . . . . . . . . . . . . A.3 Gaussian vs. Fermi-Dirac smearing . . . . . A.4 On the optimal choice of g . . . . . . . . . . 151 . 151 . 153 . . . . . . . 154 157 158 161 163 164 170 171 the local . . . . . . . . . . . . . . . . . . . . . . . . density of . . . . . . . . . . . . . . . . . . . . . . . . . . . . states175 . . . . 175 . . . . 176 . . . . 177 . . . . 178 B Local polarization via Born effective charges 181 C Complex band structure within the nearly-free electron model 185 D Resumen 187 E Conclusiones 193 Bibliography 211 Introduction The research of transition metal oxides is today in a momentous stage. The situation is indeed so exciting that it has been compared to that of semiconductor physics sixty years ago [1]. That is quite a serious comparison, since our lives today are overwhelmingly dependent on devices developed from basic material science research taking the first steps at that period. This comparison however is not gratuitous. The last decades of research on transition metal oxides have been tremendously exciting, with the discovery of an enormous number of different functionalities in these materials, from superconductivity to colossal magnetoresistance, just to cite a couple of examples. One particular family of transition metal oxides have attracted a lot of attention in the last years. This family of materials share the relatively simple perovskite parent crystal structure. The simplicity of the crystal structure, with only five atoms in the unit cell in the high-symmetry cubic reference structure, hides an enormous amount of subtle physics. These materials, all sharing a very similar atomic structure, display an extremely wide range of properties: superconductivity, ferromagnetism, colossal magnetoresistance, multiferroism, non-linear optics ... More interestingly, the wide range of properties arising from what can be considered relative materials suggest that the emergence of one particular property must be the consequence of delicate a balance between multiple interactions that are probably common to many of the members of this family of materials. Indeed, this diverse phase diagram emerges from the close competition of different interactions that takes place in these materials. While in other kinds of materials such as semiconductors or metals, one of the different interactions involved – Coulomb repulsions, strain, exchange, etc – clearly dominates over the other and determines the macroscopic properties of the system, in transition metal oxides this effects are very often of the same magnitude. As a result these materials usually display multiple competing phases and a strong susceptibility to external perturbations [2, 3]. This makes these materials ideal candidates for the design of artificial devices with tailored functionalities. One of the properties displayed by some perovskite oxides is ferroelectricity. A ferroelectric material is an insulator exhibiting at least two different states of nonzero polarization, being possible to switch between them by applying an external electric field [4]. The term “ferroelectric” was coined due to the analogy of these materials with the ferromagnets, as they both exhibit a hysteresis loop when polarization (magnetization 1 2 Introduction in the case of ferromagnet) is measured as a function of the applied electric (magnetic) field. Ferroelectrics are materials with a great applied interest [5, 6]. The property of ferroelectricity itself, i.e. the capacity of switching between two or more polarization states with the application of an external field, can be exploited for example for the fabrication of memory devices, where each state of the polarization can be assigned to the values 0 and 1 of a bit of information. This is the basic working principle of ferroelectric random access memories (FeRAM). Besides, ferroelectricity is usually associated with other properties of great interest. All ferroelectric materials, for instance, are also piezoelectric (a deformation can be induced by the application of an electric field and vice versa) and pyroelectric (temperature changes of the sample modifies the polarization), properties that are used for the fabrication of transducers, actuators or infrared detectors. One of the most successful examples is the family of PbZr1−x Tix O3 ceramics which today are present in a great variety of devices, from ultrasound imaging equipments, to fuel injectors in automobile engines or atomic-force microscopes. Ferroelectric materials posses a very large dielectric constant which is the reason for their use in the fabrication of dynamic random access memory (DRAM) capacitors. The steady miniaturization of electronic devices imposed by electronic industry and impulsed by the need of faster, but at the same time smaller and more energy-efficient electronic devices, have motivated the study of properties of ferroelectric materials at the nanoscale. It is well known that bulk properties of ferroelectric materials and most perovskite oxides are strongly affected by boundary conditions, which became specially relevant as devices became smaller. Ferroelectricity, for instance, was suggested to have a critical size of about 10 nm, below which modifications of the balance between driving interactions together with the electrostatic coupling with depolarizing fields would provoke the loss of an spontaneous polarization. Nevertheless as the synthesis and experimental characterization of ultra-thin film developed, thinner and thinner ferroelectric films were observed to preserve a remnant polarization, bringing the critical thickness down to just a few monolayers. On the other hand, the improvement of growth techniques allowed to take advantage of the subtle balance of instabilities and the strong sensitivity of these materials to the boundary conditions to tune the properties of perovskite oxide thin films. The seek of a route to design and realize artificial materials with tailored functionalities brought a great excitement to the field and boosted the research activity on these systems. However the close competition between different interactions and phases makes very difficult if not impossible to predict the properties of the artificial structure in terms of simple rules and given the known properties of the bulk constituents. This is one of the reasons for the fundamental role played by first-principles simulations in the outstanding improvements of the field during the last years [7]. The rapid evolution in the atomistic modeling of materials, driven both by the fast and steady increase of the computational power (hardware), and by important progresses in the development of more efficient algorithms (software) makes possible to describe very accurately the properties of materials using methods directly based on the fundamental 3 laws of quantum mechanics and electrostatics. Even if the study of complex systems requires some practical approximations, these methods are free of empirically adjustable parameters. For this reason, they are referred to as “first-principles” or “ab-initio” techniques. The current situation of the field is particularly exciting. On the one hand, recent breakthroughs on materials synthesis and characterization techniques have allowed the growth of ferroelectric thin films with a control at the atomic scale and the local measurement of the ferroelectric properties [8]. On the other, the steady increase in computational power and improvements in the efficiency of the algorithms permit accurate first-principles study of larger and more complex systems, overlapping in size with those grown epitaxially. This allows a continuous feedback between experiments and theoretical models. This combined effort has led, in the last couple of decades, to very significant advances in the microscopic understanding of the properties of perovskite ferroelectrics and related compounds. Nevertheless every step forward gives rise to the discovery of new phenomena (an excellent example is the discovery of conducting interfaces at superlattices of LaAlO3 and SrTiO3 , two insulating materials [9]; or the conductivity of domain walls in BiFeO3 [10]), generating new opportunities for practical exploitation of functionalities and, more importantly, rising new questions and motivating the further investigation of these materials. One problem under active investigation due to its wide implications both in the basic physical properties exhibited by ferroelectric thin films and in the potential applications, is the understanding of the screening mechanisms in such systems. The termination of the ferroelectric polarization at the surface of a film or its discontinuity across an interface with an electrode or a different insulating material generates a polarization charge which gives rise to a depolarizing field tending to suppress the polarization. Multiple mechanisms can take place in order to compensate the polarization charges: accumulation of screening charge at the electrodes, ionic adsorbates at a free surface or the breaking up of the system into polarization domains. In this thesis we have performed a first-principles study of some of these mechanisms. We have paid special attention to the methodological issues associated to the study of screening properties in ferroelectrics which can be important for the first-principles research of other interfacial properties. Then we focus on two particularly relevant systems: (i) ferroelectric/metal interfaces, ubiquitous in ferroelectric capacitors and (ii) ferroelectric/incipient ferroelectric interfaces, such as PbTiO3 /SrTiO3 superlattices, a system which is attracting a lot of interest due to the appearance of an improper ferroelectricity in the ultrathin limit. In the first case we study charge rearrangements at metal/ferroelectric junctions associated with the formation of gap evanescent states, and the formation and properties of polarization domains in these kind of devices. In the case of PbTiO3 /SrTiO3 superlattices, the discovery of an interface-intrinsic coupling of ferroelectricity with non polar instabilities, absent in the parent bulk materials, have attracted a lot of attention in the last years. We explore the phase diagram with strain, its effect on the coupling between instabilities and the properties of polydomain phases. This manuscript is organized as follows. In Chapter 1 we introduce the general 4 Introduction properties of bulk ABO3 ferroelectric materials. We discuss the different instabilities present in these compounds, their competition and the connection with the arising of ferroelectricity. We then consider how size effects and boundary conditions affect these properties, and how this can be used to our advantage allowing to fine tune perovskite oxides functionalities. Special attention is devoted in this Chapter to discuss the electrostatic boundary conditions and the different screening mechanisms that can take part in a ferroelectric thin film, which is the subject of this thesis work. In Chapter 2 we will describe the basic theoretical details of first-principles methods used to carry out the research reported in this memory. Some issues for the simulation of heterostructures associated to the theoretical approach are investigated in Chapter 3. Here we provide a clear procedure to detect spurious results consequence of the misuse of the most extended theoretical methodology, namely the density functional theory (DFT), and suggest paths to avoid them. Results of this Chapter are more than just methodological, since some screening mechanisms detected in pathological heterostructures might actually be relevant for real interfaces. Chapter 4 is devoted to the study of evanescent states in the gap of a ferroelectric in a metal/ferroelectric junction, the so called metal-induced gap states (MIGS). This states play a fundamental role in tunneling phenomena and Schottky barrier formation. In this Chapter we discuss to what extent the characteristics of these states can be predicted from bulk properties of the ferroelectric, and which are related to intrinsic interface effects. In Chapter 5 we discuss the formation of polarization domains in ferroelectric capacitors. For the first time, closure domains are predicted from first principles to form in ferroelectric thin films. Despite being considered unlikely to occur in ferroelectric thin films due to the large coupling between polarization and strain, this structure is found to be surprisingly general and to provide an extremely good screening. In Chapter 6 we study the effect of strain on the coupling between polarization and oxigen octahedra rotation in PbTiO3 /SrTiO3 superlattices. The strong coupling of these two instabilities in this system is explained in terms of a covalent model. In view of results of Chapter 5, we also consider the formation of polarization domains in the superlattices. Structures similar to those observed in the ferroelectric capacitors are found, forming vortex-like dipole arrangements at the domain walls. Finally the results of this work are summarized in the Conclusions. Chapter 1 Ferroelectric thin films 1.1 Introduction As it was mentioned before, to be a ferroelectric, a material must satisfy two conditions (i) it must exhibit at least two states of different finite polarization, and (ii) it must be possible to switch from one of these states to the other by applying an external electric field. This condition of switching shows up experimentally as a hysteresis loop when the polarization of the materials is measured as a function of the applied electric field. In the ideal hysteresis loop depicted schematically in Fig. 1.1 the two opposite values of the polarization at zero field correspond to the spontaneous polarization of the material and the coercive field is the threshold electric field to switch the polarization. In a real crystal, polarization domains and depolarizing field can make the average polarization of the sample at zero field (remnant polarization) to be smaller than the ideal spontaneous polarization Also in analogy with ferromagnetic materials, all ferroelectrics undergo a phase transition to a paraelectric phase above the Curie temperature TC . Ferroelectricity was first discovery by J. Valasek in 1920 in Rochelle salt [11] For almost three decades after these pioneering works, all known ferroelectrics were hydrogenbonded materials, and for some time this was thought to be a requirement for a given material to exhibit this property. The discovery in 1949 of ferroelectricity in BaTiO3 , a much more robust material, with a much simpler crystal structure, stimulated the use of ferroelectric compounds for practical applications. This, in turn encouraged theoretical research of these materials beyond simple scientific curiosity and, thanks in part to the simplicity of the crystal structure of BaTiO3 , the understanding of the physics behind the ferroelectricity evolved rapidly. BaTiO3 became then the prototype of a whole family of materials, the perovskite oxides, which still today are providing huge amounts of new physics thanks to the tunability of their numerous properties. This family of materials have in common a crystal structure derived from the ideal cubic perovskite, with a formula unit usually denoted as ABO3 , where A is a mono-, di- or tri-valent cation and and B is a penta-, tetra- or tri-valent cation respectively. In the centrosymmetric cubic structure these all materials derive from, A atoms are located at the corners of the unit cell and oxygen atoms are at 5 6 Chapter 1. Ferroelectric thin films P +P0 Ec E -P0 Figure 1.1: Idealized hysteresis loop that would correspond, for instance to the switching process of a single unit cells of a ferroelectric material. The values of the spontaneous polarization P0 and the coercive fields Ec are shown. the center of the cube faces, forming an octahedra at which center is the B atom. This structure corresponds for instance to the high temperature, cubic, non polar phase of BaTiO3 , which unit cell is represented in Fig. 1.2(a). In ferroelectric materials, below the Curie temperature, this non polar ideal cubic structure is unstable and present distortions compatible with an spontaneous polarization. In the most simple cases – like for instance in the temperature-driven cubic-to-tetragonal phase transition in BaTiO3 at 130 ◦ C – this distortion consist of an opposing shift of B cation and the oxygen octahedra, as in Fig. 1.2(b). The atomic displacements are accompanied by a shape distortion of the unit cell caused by the symmetry reduction. 1.2 Ferroelectricity in bulk Most perovskite oxides exhibit different instabilities that distort the crystal structure from the ideal cubic one. The stability of the high symmetry structure is very often discussed in terms of a steric model, in which the size of A and B cations determine the possible symmetry-lowering distortions that might emerge. The tendency of ABO3 to undergo a given phase transition to a state with lower symmetry is usually quantified through the Goldschmidt tolerance factor RA + RO τ=√ , 2RB + RO (1.1) which is equal to 1 when the atomic radii of A (RA ) and B (RB ) cations, and oxygens (RO ) are such that the latter just touch the cations. For τ > 1, the B cation has free space around and tend to move off-center, generating dipoles that might align cooperatively between neighboring unit cells and giving rise to ferroelectric order. If on the contrary 7 1.2. Ferroelectricity in bulk (a) (b) Figure 1.2: Unit cell of the prototypical ferroelectric BaTiO3 in the (a) non-polar cubic configuration and (b) the tetragonal ferroelectric phase. The polar mode in the ferroelectric phase is associated in most materials with an elongation of the unit cell in the polarization direction, as sketched in (b). τ < 1 the larger B cation “pushes” the oxygens out of the center of the faces favoring rotations of the oxygen octahedra. This model provides a simplistic yet intuitive tool to understand the relative stability of some common distortions in ABO3 compounds, but we need a more detailed analysis of the underlying physical effects to be able to understand some subtle phenomena that take place at the interfaces of these materials, which is the final goal of this work. 1.2.1 Soft modes and double well energy These instabilities are associated with the existence of “soft modes” in the phonon band structure of the ideal cubic crystal [12]. A vibrational normal mode is said to soften when the condensation of the atomic displacements associated to its eigenmode leads to a decrease in energy of the system. There is not, in this case, a restoring force bringing the atoms back to the – unstable – reference equilibrium position, but a driving force that distort the system into a lower symmetry, stable configuration, with an energy below that of the centrosymmetric one. The curvature of the energy surface with respect to the amplitude of the soft mode, or conversely the associated force constant within the harmonic approximation, is negative and its frequency, ω, imaginary. In some cases these instabilities lead to a polarization of the system. In the particular case of BaTiO3 , it exhibits a mode at Γ which eigenmode, depicted schematically in Fig. 1.2(b), involves a displacement of the Ti atoms in opposition to the oxygen cage. The opposite shift of positive and negative charges gives rise to the polarization of the system. The value of the imaginary frequency ω associated with the soft mode measures to some extent the strength of the instability in the harmonic approximation. However, for the distortion from the cubic reference structure to lead to a different stable structure we need to consider also the effects of anharmonicity. In many of the most 8 Chapter 1. Ferroelectric thin films Figure 1.3: Double well potential energy curve with respect to the normalized amplitude of the distortion ξ, for bulk tetragonal BaTiO3 . Bottom row show schematically the structure at the energy minima (left and right for a downward and an upward pointing polarization respectively) and at the reference unstable configuration (central). common perovskite ferroelectrics the final polar structure can be actually obtained from the eigendisplacements of one single mode (typically a polar mode at Γ). Assuming a relatively smooth variation of the energy with respect to the distortion, the energy of the system can be expressed as a Taylor expansion in the amplitude of the distortion with respect to the cubic reference structure. If ξ is the amplitude of the distortion, proportional to a given eigenmode, the potential energy of the system can be expanded as 1 1 1 U(ξ) = α2 ξ 2 + α4 ξ 4 + α6 ξ 6 , 2 4 6 (1.2) where we have truncated to sixth order. Only even terms are allowed in the expansion as a consequence of the cubic symmetry of the reference structure. The quadratic term is the harmonic contribution and is related to the curvature of the energy at ξ = 0. It is proportional to the square of the imaginary frequency associated to the soft mode, ω 2 , so it must be negative for the polar distortion in a ferroelectric. Nevertheless, this term alone would lead to infinite displacements of the atoms from the high symmetry positions. Higher order terms are positive and take into account anharmonic effects that are responsible of the stabilization of the distortion. If the potential energy is plotted as a function of the amplitude of the soft mode 9 1.2. Ferroelectricity in bulk Table 1.1: Born effective charges of some ABO3 perovskites. O1 denotes the apical oxygen and O2 the equatorial one (see Fig. 1.2). All charges have been calculated with the Siesta code. BaTiO3 PbTiO3 SrTiO3 A 2.640 3.870 2.527 B 7.370 7.030 7.555 O1 -5.700 -5.760 -5.951 O2 -2.155 -2.570 -2.066 one obtains the double well potential energy, characteristic of ferroelectrics and shown in Fig. 1.3. The amplitude of this distortion can be associated with the polarization of the system and thus, the two energy minima of the potential energy curve correspond to the two equivalent states with P equal to the spontaneous polarization 1.2.2 Anomalous dynamical charges The contribution of a lattice distortion to the polarization of the material can be quantified introducing the concept of Born effective charges [13, 14]. For each atom i in the unit cell, the Born effective charge tensor is defined as the change to linear order in the polarization along direction α induced by a small displacement of the atomic sublattice along direction β, ∂Pα ∗ Zi,αβ = Ω , (1.3) ∂xi,β E=0 where Ω is the volume of the unit cell, and the polarization is calculated at zero electric field. Due to the cubic symmetry of the reference structure in perovskites, the tensor becomes diagonal. For A and B atoms, the tensor only displays one independent entry. Then the tensor can be considered as an scalar and a single Born effective charge is associated to A and B atoms. On the contrary, in tetragonal ferroelectrics the polarization direction differentiates oxygen atoms into apical (usually denoted O1, at the unit cell face perpendicular to the polarization direction) and equatorial (O2, at the faces parallel to polarization direction, see Fig. 1.2). Consequently two different Born charges are associated to oxygen atoms depending on the direction of the polarization (see Table 1.1). The Born effective charges are defined for a change induced in the polarization at zero electric field. Similarly effective charges for zero electric displacement field can be defined, which are called Callen charges. In Table 1.1 we report the Born effective charges of some common perovskite oxides that are relevant to this work. All these materials are characterized by effective charges significantly larger than the nominal ones (+2 for the A atoms, +4 for B atoms and -2 for oxygens for these three compounds). The anomalously large effective charges reflect the fact that the electronic cloud of a given ion does not rigidly follow the core as it displaces out of the reference configuration, but the displacement triggers a polarization 10 Chapter 1. Ferroelectric thin films Partial O 2p - B d hybridization Harrison's model Anomalously large Z* associated to macroscopic electronic currents For the specific displacement patter associated with the ferroelectric mode Giant destabilizing dipole-dipole interaction Cochran's model Ferroelectric instability Figure 1.4: Flowchart summarizing the origin of ferroelectricity in ABO3 compounds in connection with the hybridization between oxygen 2p and B cation 3d orbitals. (Adapted from Ref. [13]) of the atomic orbitals and a transfer of charge through the cation-oxygen bond that contributes to the polarization of the material. A large anisotropy of these charges, with the effective charge of apical oxygens (oxygens in the faces perpendicular to the displacement direction) also reflects the strong hybridization that takes place along the B-O chains, in contrast with the much weaker interaction with the equatorial oxygens. 1.2.3 Origin of the ferroelectricity Following the classical interpretation of Cochran [12], the stabilization of a polar distortion, and consequently the origin of ferroelectricity, relies on the competition between long range dipole-dipole interaction, which favor the development of a polarization, and short range forces that tend to destabilize polar configurations. In this context long range interactions contribution is enhanced by large values of the Born effective charges that give rise to giant dipolar interactions and contributes to the softening of the phonon with a negative contribution to ω 2 , destabilizing the reference cubic structure. The polar distortion becomes then an instability of the reference cubic structure. In the case of BaTiO3 and SrTiO3 , Born charges of A atoms and equatorial oxygens are relatively close to the nominal ones and main contribution to polarization comes from the atomic chains formed by Ti atoms and apical O. This reflects the fact that 11 AFD mode at R: AFD mode at M: 1.2. Ferroelectricity in bulk Figure 1.5: Schematic view of AFD modes at M [(a) side and (b) top view] and R [(c) side and (d) top view], consisting respectively in in-phase and out-of-phase oxygen octahedra rotations. Using Glazer notation these two modes can be denoted by a0 a0 c+ and a0 a0 c− respectively. polar distortions in this compounds are driven by the hybridization of the empty Ti 3d orbitals with the occupied O 2p orbitals. Meanwhile A atoms remain essentially inert during the condensation of the polar instability. In other cases, like PbTiO3 , covalency of Pb-O bonds play a significant role in the ferroelectric instability, and there is a sizable contribution to the spontaneous polarization of the material from the opposite shift of Pb and O apical atoms in the same plane, which reflects in the large Born effective charges of these atoms. 1.2.4 Non-polar instabilities Many of these materials also exhibit non polar, Brillouin zone boundary antiferrodistortive (AFD) instabilities, consisting in rotations of the oxygen octahedra. These instabilities also lower the symmetry of the system from the cubic structure, but involving only rotations of the negative charges around the inversion center they do not give rise to any polarization. Interestingly the energy balance between long and short range forces is, in this case, the opposite than for the polar modes, with short range repulsion favoring 12 Chapter 1. Ferroelectric thin films rotations. As a consequence, even though both ferroelectric and AFD instabilities might be present in the phonon dispersion curves of the cubic structure, these two instabilities usually compete and the ground state of these perovskites typically display either one or the other, but rarely both type of distortions. SrTiO3 for instance displays both ferroelectric and AFD modes with imaginary frequencies in the cubic phase. Freezing any of these instabilities individually leads to a decrease in the energy of the crystal. However the coupling term between the polar and AFD modes is positive and both modes compete to suppress each other [15]. As a result, and despite the large effective charges of this material that softens the polar mode at Γ, the ground state of SrTiO3 only displays AFD distortions. Nevertheless, the presence of a polar soft mode shows up in this material as a great polarizability and dielectric constant. Oxygen octahedra rotation patterns can be described in a compact way using Glazer notation [16]. According to this notation three indexes are used referring to the rotation along directions parallel to the three unit cell vectors respectively (the first one describes the rotations around the [100] direction and so on). Each index is in turn composed by a symbol describing if the rotations of successive octahedra along a given direction (denoted by a, b or c) are in-phase (+), out of phase (−) or no rotation takes place (0). For example, ground state of bulk SrTiO3 can be expressed within this notation as a0 a0 c− , meaning that oxygen octahedra rotate out-of-phase around the [001] axis, see Fig. 1.5. 1.3 Ferroelectric thin films As discussed above, ferroelectricity in most common ABO3 perovskites is linked to spontaneous atomic off-center displacements, resulting from a delicate balance between longrange dipole-dipole Coulomb interaction and short-range covalent repulsions. In ultrathin films and nanostructures, both interactions are modified with respect to the bulk. Size effects on short range interactions are conceptually simpler to understand. They are modified by the presence of surfaces and interfaces which alter the chemical environment. They are also affected by changes in the unit cell size and shape induced by pressure and homogeneous or inhomogeneous strains determined by the mechanical boundary conditions. Effects on the dipole-dipole interactions are more subtle. To understand some of the properties of ferroelectrics and particularly the size effect of this materials it is important to note that the driving force for ferroelectricity, namely the dipole-dipole interaction, posses an intrinsic collective character. While short-range forces act essentially on each individual atom repelling any polar distortion, long range dipole-dipole destabilizing interaction buildup from the alignment of localized dipoles within a correlation volume [17]. Furthermore, dipole-dipole forces are extremely anisotropic. They favor the parallel alignment of dipoles along the polarization axis, forming chains of dipoles aligned longitudinally. But at the same time, interactions within the plane perpendicular to the polarization of the dipoles favor anti-parallel arrangement. Depending on the geometric arrangement of the dipoles in the lattice the overall balance will favor either the 1.3. Ferroelectric thin films 13 parallel or antiparallel alignment of dipole chains, to form respectively a ferroelectric or antiferroelectric material. This anisotropic character of the dipole-dipole interaction implies an anisotropic correlation volume, meaning that the energy penalty due to the loss of dipole-dipole interactions is considerably higher in a perpendicularly polarized thin-film geometry than in other geometries. This, with the development of depolarizing fields as a result of polarization discontinuities (discussed in Sec. 1.3.2), suggest a finite-size effect on the ferroelectric properties of ferroelectric thin films. The occurrence of a size effect would have important implications for applications, since it would limit the minimum useful thickness of these materials. In fact, until the late 1990’s, it was widely accepted that ferroelectricity in perovkite oxides would disappear below a critical thickness of about 10 nm as a consequence of the lost of long range interactions, and the arising of depolarizing electrostatic fields. This assumption proved to be erroneous and revealed that the delicate balance between all these variables and the boundary conditions hampers the prediction of the behavior of finite-sized ferroelectric samples. The complex coupling between instabilities and the different boundary conditions can actually be taken to our advantage. A deep understanding on how boundary conditions affect ferroelectricity and other properties of perovskite oxides in finite samples, together with the atomic control achieved in the growth of this materials, allow to build artificial systems in which we can play with the boundary conditions to engineer new functionalities. However the fact that many of the most spectacular examples of new functionalities in artificial systems have been found unexpectedly is a good prove that there is still a lot of research to be done in this direction. This was for instance the case of the appearance of metallic [9] (or even superconducting [18]) interfaces at the boundary between two band insulators LaAlO3 and SrTiO3 , or the discovery of improper ferroelectricity in PbTiO3 /SrTiO3 superlattices driven by a coupling between polar and non-polar instabilities not present in the parent materials [19]. The pertinent question is then, what new properties will we be able to engineer once a better understanding of the physical processes involved at oxide interfaces is achieved? 1.3.1 Mechanical boundary condition The coupling between different instabilities – polar and non polar – with strain is well known to be specially strong in ferroelectric perovskite oxides, and can have a substantial impact on the structure, transition temperatures, dielectric and piezoelectric responses. This opened the door to the possibility of tunning functionalities in these compounds by playing with the strain, what led to the coinage of the term “strain-engineering”. In ferroelectric thin films, homogeneous strain can be achieved by means of the epitaxial growth of the film on a substrate with a different lattice parameter. Thanks to the availability of multiple perovskite substrates with a wide variety of in-plane lattice parameters, we can now fine tune the ferroelectric and related properties in thin films by using the homogeneous strain almost as a continuous knob. One key factor to achieve the exceptionally wide range of stains that can be obtained with today’s growth techniques is the fact that both the ferroelectric and the substrate share a very similar crystal structure. This facilitates the coherency of in-plane crystal structure at the interface. 14 Chapter 1. Ferroelectric thin films Assuming perfect coherency, the strain is defined as a function of the bulk lattice a −a0 parameters of the film material, a0 , and of the substrate, ak , as = ka0 . The clamping between the film and the substrate onto which it is deposited can be maintained only in ultrathin films, where the elastic energy stored in the overlayer is still relatively small. For thicker films a progressive relaxation and lost of coherency with the substrate will occur via formation of misfit dislocations, which generally cause a degradation in film quality. Note that, in general, the strain state of the film will also depend on the differences in the thermal evolution of the lattice parameters of the substrate and the film material. The different thermal expansion coefficients of substrate and films material also opens a door for the design of pyroelectric devices with enhanced performance. In order to understand the effect of the “polarization-strain” coupling, let us generalize the expansion of the potential energy of Eq. (1.2) in terms of additional strain ij (where i and j are cartesian directions) degrees of freedom. In the paradigmatic example of a tetragonal ferroelectric film (e.g. PbTiO3 or BaTiO3 at room temperature) epitaxially grown on a (001) cubic substrate (like SrTiO3 ) we have mixed strain/stress boundary conditions: on the one hand the in-plane strains xx = yy are fixed by the lattice mismatch between the ferroelectric and the substrate, while xy = 0. On the other hand, the out-of-plane strain zz and the shear strains xz and yz are free to relax (condition of zero stress: σzz = σxz = σyz = 0). Assuming for simplicity only an homogeneous polarization along z-direction, vanishing shear strains, and restricting the expansion to leading orders in ξ and , the free energy functional to be minimized now reads [20, 21] U(ξ, ) = 1 1 1 α2 ξz2 + α4 ξz4 + α6 ξz6 2 4 6 1 1 + C11 (22xx + 2zz ) + C12 (22xx + 4xx zz ) 2 2 +2g0 xx ξz2 + (g0 + g1 )zz ξz2 . (1.4) The terms in the first line correspond to the double-well energy of Eq. (1.2). The terms in the second line are the elastic energy while the terms in the third line arise from the coupling between ionic and strain degrees of freedom. They correspond to the so-called “polarization-strain coupling” and are at the origin of the piezoelectric response. It is clear from Eq. (1.4) that the polarization-strain coupling terms are responsible for a renormalization of the quadratic part of U that now takes the form 1 α2 + 2g0 xx + (g0 + g1 ) zz ξz2 . 2 (1.5) Depending on the value of the parameters g0 and g1 , and of xx and zz (deduced from the relation ∂U/∂zz = 0 which follows from the boundary condition σzz = 0), we see that, playing properly with the epitaxial strain conditions, it is possible to make the coefficient α2 more negative (i.e. induce a ferroelectric material to be even more ferroelectric, or 1.3. Ferroelectric thin films 15 even induce a non-ferroelectric material to become ferroelectric [22, 23]), or to make α2 positive, thus suppressing the ferroelectric character of the film. The first milestone theoretical work on the influence of the strain in ferroelectric polarization is due to Pertsev et al. [20], who identified the right “mixed” mechanical boundary conditions of the problem (fixed in-plane strains, and vanishing out-of-plane stresses), and computed the corresponding Legendre transformation of the standard elastic Gibbs function to produce the correct phenomenological free-energy functional to be minimized. Then, they introduced the concept now known as “Pertsev phase diagram”, of mapping the equilibrium structure as a function of temperature and misfit strain, which has proven of enormous value to experimentalists seeking to interpret the behaviour of epitaxial thin films and heterostructures. These kind of diagrams were produced for the most standard perovskite oxides, either fitting the parameters of the energy expansion to the experiment (usually near the bulk ferroelectric transition) (see for instance Ref. [20]), or performing first-principles studies (see Ref. [24] for full sequences of epitaxially-induced phase transitions for some of the most common oxide perovskites). From all these theoretical studies, a general trend of the strain-induced phase transitions emerged for perovskite oxides on a (001) substrate [24]: sufficiently large epitaxial compressive strains tend to favor a ferroelectric c-phase with an out-of-plane polarization along the [001] direction; conversely, tensile strains usually lead to an aa-phase, with an in-plane P oriented along the [110]direction. The behavior at an intermediate regime is material-dependent, but the general trend is that the polarization rotates continuously from aa to c passing through the [111]-oriented r-phase. In non-ferroelectric perovskites like SrTiO3 and BaZrO3 the intermediate regime is non-polar, while in PbTiO3 the formation of mixed domains of c and aa phases could be favorable. From the experimental side, there have been impressive advances as well. For instance, dramatic effects were observed experimentally by Haeni et al. [22] were room temperature ferroelectricity was obtained in otherwise paraelectric SrTiO3 . The substrate used was DyScO3 which produces a +1% strain leading to an in-plane polarization and bringing TC close to room temperature. Another example of strain-engineering was demonstrated by Choi et al. [25], with a large enhancement of ferroelectricity induced in strained BaTiO3 thin films by using a biaxial compressive strain imposed by coherent epitaxy on single-crystal substrates of GdScO3 and DyScO3 . The strain resulted in a ferroelectric transition temperature nearly 500 K higher than the bulk one and a remanent polarization at least 250% higher than bulk BaTiO3 single crystals. Very recently, another spectacular strain effect was demonstrated both experimentally and theoretically [26, 27]: multiferroic BiFeO3 films undergo an isosymmetric phase transition to a tetragonal-like structure with a giant axial ratio [28] when grown on a highly compressive substrate such as LaAlO3 . Furthermore, both phases appear to coexist [26] in some conditions, with a boundary that can be shifted upon application of an electric field. This appears to be by far the largest experimentally realized epitaxial strain to date, of the order of 4-5 %; the existence of this new phase of BiFeO3 was also predicted to be promising for enhancing the magnetoelectric response of this material [29]. 16 Chapter 1. Ferroelectric thin films As mentioned above, coherency between the substrate and the thin films lattice constants can be maintained only up to a limiting thickness, after which defects and misfit dislocations start to form. Strain relaxation leads to inhomogeneous strain fields (or strain gradients), which can have profound consequences on the properties of the thin film. A strain gradient intrinsically breaks the spatial inversion symmetry and hence acts as an effective field, generating electrical polarization even in centrosymmetric materials. This phenomenon became known as flexoelectricity, by analogy with a similar effect in liquid crystals, and is allowed in materials of any symmetry. Strain-gradient-induced polarization has, for instance, been measured in single crystals of SrTiO3 , an incipient ferroelectric (but non-polar in bulk) material [30]. Flexoelectric effects can play an important role in the degradation of ferroelectric properties [31, 32] and therefore proper management of strain gradients is crucial to the performance of ferroelectric devices. At the same time, an increasing amount of research is now aimed at exploiting flexoelectricity for novel piezoelectric devices. The possibility of generating a piezoelectric response in any dielectric material [33], irrespective of its symmetry, by carefully engineering strain gradients has generated a lot of excitement in the field (see, for instance, the review by L. E. Cross [34]). At the same time, fundamental questions about flexoelectricity are being revisited, and modern first-principles-based approaches [35, 36] are being devised to go beyond existing phenomenological theories [37]. Exhaustive discussions on strain effects on ferroelectric thin films can be found in Ref. [38] (combined experimental and theoretical report), and in Refs. [39] and [40] (more focused on the theoretical point of view) 1.3.2 Electrical boundary condition From basic electrostatics we known that any discontinuity of the polarization at a surface or an interface gives rise to an accumulation of bound charges [41], ∇P = −ρb . (1.6) This is true for any geometry of a finite ferroelectric sample, but has dramatic consequences in the case of thin-films made of a uniaxial ferroelectric material with an out-of-plane polarization, which is the desired configuration for many practical implementations such as ferroelectric memories. The presence of unscreened bound charges at the surfaces or interfaces leads to the arising of a depolarizing field that is generally strong enough to suppress completely the spontaneous polarization of the film. The limit case is a free-standing slab with an out-of-plane polarization Pz and under open circuit boundary conditions. In this situation the condition of the continuity of the electric displacement, Dz , across the surface translates into Dzslab = ε0 E + Pz = Dzvacuum = 0, which gives an electric field inside the slab of (1.7) 17 1.3. Ferroelectric thin films Ed = − Pz . ε0 (1.8) The field in Eq. (1.8) points opposite to the polarization and thus the energy term corresponding to the interaction of the polarization with the electric field, proportional to −EP , is positive, opposing to the polarization of the slab. This field is called the depolarizing field. It is important to note that Pz in Eq. (1.7) and (1.8) is the total polarization relaxed in the presence of the depolarizing field, meaning that both sides of the identity in Eq. (1.8) must be self-consistent. We can obtain an idea of the magnitude of this field introducing the spontaneous polarization of BaTiO3 , about 30 µC/cm2 , in Eq. (1.8). This yields a value of ∼ 30 GV/m, that might be compared with the coercive fields of bulk ferroelectric materials, that typically are of the order of several tens of MV/m. These considerations suggest that the presence of an unscreened depolarizing field will completely suppress the out-of-plane polarization of a ferroelectric slab. For this reason, much of the theoretical and experimental research in ferroelectric thin films is connected directly or indirectly with the study of screening mechanism in these systems. Arguments discussed above suggest that a ferroelectric thin film with a free surface should not be able to sustain an out-of-plain polarization [irrespective of its thickness, since Eq. (1.8) is independent of this variable]. Nevertheless, this conclusion contrast with the experimental evidence. Lots of experiments concerns measurements on ferroelectric films with open surfaces that can, for instance, be switched locally applying a voltage with a piezo-force microscope tip. Different models and first-principles simulations suggest that in ambient conditions the compensating charges necessary to stabilize an out-of plane polarization in a film with an open surface could be provided mostly by chemical adsorbates (water molecules, OH groups, CH, etc.) [42, 43, 44]. Screening efficiency of the molecular adsorption was demonstrated by Wang et al. [45], who achieved the polarization switching of a PbTiO3 film by varying the partial oxygen pressure at the open surface. Different mechanisms can be invoked to provide the screening of the depolarizing fields in finite-sized ferroelectric samples, including the adsoption of molecualr groups just discussed. Most of them are summarized in Fig. 1.6. In the next sections we discuss some of the most relevant. Imperfect screening by metallic electrodes The most evident solution for the screening of the depolarizing field is to sandwich the ferroelectric film between two metallic electrodes in short circuit. Assuming ideal electrodes, the free charges would overlap with the bound charges at the surface, providing a perfect screening of the depolarizing field. However, this is not what happens in real electrodes, even in structurally perfect ones. Two models are typically invoked to explain the origin of the imperfect screening: (i) the finite screening length, (ii) and the appearance of a “dead layer” at the metal/insulator interface. According to the first one, the screening charges in the metal distribute over a region of finite depth. The key parameter in this case is the distance from the interface to 18 Chapter 1. Ferroelectric thin films +–+–+–+– +– +– + – Ps –+–+–+– +– +– +– + Finite conductivity λeff V λeff Suppression of polarization ––––––– +++++++ Ps ––––––– +++++++ Ps Polarization rotation Metallic electrodes – – + Ps=0 ––––––– +++++++ Ps ––––––– +++++++ +++++++ Ps Edep ––––––– Ps PE Unstable Ps FE Ps PE + +` – Atmospheric adsorbates Continuity of polarization Polarization vortices 180° Closure Domain formation Figure 1.6: The depolarization field arising from unscreened bound charges on the surface of the ferroelectric is generally strong enough to suppress the polarization completely and hence must be reduced in one of a number of ways if the polar state is to be preserved. Much of the research on ultrathin ferroelectrics thus deals directly or indirectly with the question of how to manage the depolarization fields. The left part of the diagram illustrates screening by free charges from metallic electrodes, ions from the atmosphere or mobile charges from within the semiconducting ferroelectric itself. Note that even in structurally perfect metallic electrodes, the screening charges will spread over a small but finite length, giving rise to a non-zero effective screening length λeff that will dramatically alter the properties of an ultrathin film. Even in the absence of sufficient free charges, however, the ferroelectric has several ways of preserving its polar state, as shown in the right part of the diagram. One possibility is to form polarization domains that lead to overall charge neutrality on the surfaces. Typical domain structures discussed in the literature are 180◦ (or Kittel domains) and closure domains (also refered as Landau-Lifshitz domains). Under suitable mechanical boundary conditions, another alternative is to rotate the polarization into the plane of the thin ferroelectric slab. In nanoscale ferroelectrics polarization rotation can lead to vortex-like states generating “toroidal” order. In heterostructures such as ferroelectric-paraelectric superlattices, the non-ferroelectric layers may polarize in order to preserve the uniform polarization state and hence eliminate the depolarization fields. If all else fails, the ferroelectric polarization will be suppressed.(Reprinted from Ref. [46], courtesy of P. Zubko from Université de Genève.) 19 1.3. Ferroelectric thin films P ୈ୐ ଴ ஽௅ ௘௙௙ ଴ V(z) Metal FE Metal t ୣ୤୤ ஽௅ ୣ୤୤ ஽௅ ஽௅ ஽௅ Figure 1.7: Schematic representation of a symmetric ferroelectric capacitor under short circuit. t is the thickness of the ferroelectric (FE) layer, P is the polarization and Ed is the residual depolarizing field. The ferroelectric film is assumed to be separated from the electrodes by a vacuum (within the imperfect screening model) or a dielectric (within the dead layer model) layer, with a thickness of λeff or λDL respectively. The thick line represents the electrostatic potential. the center of mass of the screening charge distribution, usually denoted as λeff (see Fig. 1.7) [7]. The value of λeff measures the degree of screening provided by the electrodes, being zero the limit of ideal metallicity. It is tempting to relate this effective screening length with the Thomas-Fermi screening length, λTF , used in macroscopic models, but the latter is a bulk parameter of the electrode while the former is an interface-intrinsic property, dependent on the chemical details of the interface, such as its orientation or the combination of materials [47]. The dead layer, on the other hand, is a region at the metal/insulator interface with degraded ferroelectric properties that behaves as a linear dielectric with a low permittivity [48, 49, 50]. In this case, the the thickness of the dead layer λDL and its permittivity εDL determine the level of screening. In fact both models are perfectly equivalent and, regardless of the interpretation, the deviation from the ideal screening can be quantified by the ratio λeff = λDL /εDL , which is indeed the only relevant magnitude. If we consider, for instance, the dead layer model, we know that at the interface between the ferroelectric and the dielectric layer, the normal component of the electric displacement field, D, must be preserved. Therefore, and homogeneous electric field appears inside the dead layer, of magnitude EDL = D , ε0 εDL (1.9) where D is the electric displacement field within the ferroelectric. The electric field EDL 20 Chapter 1. Ferroelectric thin films causes a potential drop, ∆VDL = EDL λDL , at each interface. The short circuit boundary condition requires that the potential across the whole capacitor vanishes, so 2 D λDL + ∆VFE = 0, ε0 εDL (1.10) where ∆VFE is the potential drop across the ferroelectric layer. As a consequence, an electric field arises inside the ferroelectric (see Fig. 1.7), with a magnitude of Ed = ∆VFE 2λDL D =− . t ε0 εDL t (1.11) As mentioned above, this is the same expression one gets from the finite screening length model, simply substituting λeff = λDL /εDL Ed = − 2λeff D . ε0 t (1.12) Eq. (1.11) can also be obtained from the internal energy of the system. This derivation is particularly interesting because it connects the electrostatics of the system with the internal energy profile of the ferroelectric material. We will make use of it in Chapter 3. The relation between the polar soft mode of a ferroelectric [which is in most cases the order parameter, see Eq. (1.2)] and the polarization, often makes it useful to expand the internal energy of a ferroelectric in terms of the polarization, as in Devonshire-GinzburgLandau theories. However, the parametrization in P does not reflect a realistic setup. In an experiment or a first principles simulation we usually do not have direct control over the value of P . Instead the polarization of the material reacts in the presence of an internal electric field determined by the electrostatic boundary conditions. In first principles calculations, these might be a fixed electric field (equivalent to a fixed voltage in a capacitor in closed-circuit; short-circuit boundary condition is a particular case where the potential drop across the system is zero) or electric field displacement (equivalent to a capacitor in open-circuit with fixed free charges on the electrodes) [51, 52]. From a fundamental point of view, it is more appropriate to expand the internal energy per unit cell of the ferroelectric in terms of D as Ub (D) = A0 + A2 D2 + A4 D4 + O(D6 ). (1.13) Here A0 is an arbitrary reference energy, A2 is negative and the higher expansion coefficients are positive. The internal energy of Eq. (1.13) implicitly contain all the complexity of the microscopic physics, including the internal ionic and electronic coordinates, and the electrostatic energy due to macroscopic electric fields [51]. For a ferroelectric capacitor within the dead layer model, as depicted in Fig. 1.7, we make use of the continuity of D again and, knowing that the internal energy density of a linear dielectric is 12 ED, we write the internal energy density of the interface regions as D2 /(2ε0 εDL ). The total internal energy of a capacitor made of an N -unit-cells-thick ferroelectric film between two symmetric dead layers is thus 21 1.3. Ferroelectric thin films D2 , (1.14) 2ε0 εDL where S is the surface cell area. In short circuit the potential drop across the whole system must be zero. It follows from elementary electrostatics [51] that the internal electric field, E(D), is the derivative of U (D) with respect to D, UN (D) = N Ub (D) + 2SλDL 1 dU (D) . (1.15) Ω dD Combining Eq. (1.15) and (1.14), the short circuit electrostatic boundary condition can be written as E(D) = D dUb (D) = 0. + 2SλDL dD ε0 εDL The electric field inside the ferroelectric layer is N (1.16) 1 dUb (D) 1 dUb (D) = , (1.17) Ω dD Sc dD where c is the bulk out-of-plane lattice constant of the ferroelectric. Introducing Eq. (1.17) into (1.16), and using t = N c as the thickness of the ferroelectric layer, we end up with the following expression for the residual depolarizing field Ed = 2λDL D , (1.18) ε0 εDL t which, as we anticipated, is the same expression we obtained before from purely electrostatic arguments. Even though the polarization is not the control parameter in most of the cases, it is the order parameter (or at least a magnitude we are interested in monitoring) in typical theoretical or experimental studies of ferroelectric systems. For this reason it is useful to have an expression for the residual depolarizing field in terms of the polarization. Substituting D = ε0 Ed + P in Eq. (1.12) we get the well known expression for the depolarizing field in terms of the polarization of the ferroelectric film Ed = − Ed = − 2P λeff . ε0 t 1 + 2λteff (1.19) We should emphasize here that P in Eq. (1.19) is not the spontaneous bulk polarization nor the polarization calculated from the Born effective charges (which does not take into account the polarization of the electronic cloud, recall that the Born effective charges are obtained, by definition, at zero electric field), but the total polarization in the presence of the field Ed . Often, the approximation λeff t is assumed [53, 54], transforming Eq. (1.19) into Ed = − 2P λeff . ε0 t (1.20) 22 Chapter 1. Ferroelectric thin films CDL CN CDL Figure 1.8: Series of capacitors modeling the influence of the imperfect screening in a ferroelectric capacitor. The device as a whole behaves like a series of capacitors with CN being the “ideal” capacitance of the ferroelectric (FE) film and CDL being the capacitance of the interface regions. The formation of a layer with degraded metallic properties at the interfaces of a capacitor also affects another characteristic property, its capacitance. The presence of the interfacial layer causes a significant reduction of the capacitance of the system as a consequence of the interface region with degraded permittivity. The total capacitance of the device can be calculated a as a series of capacitors (see Fig. 1.8) 1 2 1 = + , C CDL CN (1.21) where CN is the expected capacitance of the insulator/ferroelectric condenser assuming perfect screening of the electrodes, and CDL is the capacitance intrinsic to the interfacial layer. The interfacial capacitance is, of course, linked to the properties the dead layer as Ci = εDL ε0 S ε0 S = λDL λeff (1.22) Regardless of the model used to quantify the screening in a capacitor, the physical origin of the imperfect screening can be due to different factors, depending on the system, its component materials and growth conditions. It might be due to extrinsic effects such as the damage of the surface of the electrode during deposition of the ferroelectric film, impurities or oxygen vacancies, that deteriorates the interface and creates a layer with degraded properties where neither the electrodes nor the ferroelectric behave as the bulk material. In atomically perfect interfaces the origin of the imperfect screening lies on the intrinsic finite screening length of the metal, the modified chemical environment at the interface or the penetration of conduction states into the insulating film. The effect of the depolarizing field arising from the imperfect screening of the polarization charge is sizable for films up to 10 nm [54], causing the monotonic reduction of the spontaneous polarization and Curie temperature of ferroelectric films as the thickness is reduced. Ultimately the electrostatic energy term becomes too large, a monodomain configuration is now longer supported and ferroelectricity is lost. Below this critical thickness the film either becomes paraelectric or breaks into domains of polarization. Although the use of realistic metallic electrodes with finite screening length is usually assumed to be linked with a detriment of the ferroelectric properties of the capacitor, 23 1.3. Ferroelectric thin films this might not be always the case. We have seen above that the only parameter determining the ability of a ferroelectric film of retaining a monodomain polarization is the interface-intrinsic effective screening length, and not the bulk screening length of the metal. The former parameter contains all the microscopic details of the interface, such as the local electronic and ionic structure and the chemical bonding. The detailed understanding of the relationship between the microscopic phenomena involved in the charge rearrangements at the interface and its macroscopic manifestation could actually lead to the design of interfaces with enhanced screening properties. The main effect of the interface is to alter the short-range interactions which tend to suppress the ferroelectricity. A careful choice of metallic electrode and interface termination could cause an effective decrease in the magnitude of short range repulsions, enhancing locally the ferroelectricity of the film. The proof of concept of this mechanism was first proposed for BaTiO3 /Pt capacitors by M. Stengel and coworkers [47]. First-principles simulation on the realistic capacitor, with explicit treatment of the Pt metallic electrodes, showed that at the BaO3 /Pt interface the bonding between Pt and oxygen and the repulsion of the Ba atoms lead to a dipole at the interface that contributes to enhance the local polarization of the ferroelectric film. In the limit of ultrathin films the contribution of the “interfacial ferroelectricity” could increase the polarization of the ferroelectric films even beyond the spontaneous polarization of bulk BaTiO3 Polarization domains The formation of polarization domains is an alternative mechanism to avoid the accumulation of polarization charge at the surface or interface of a ferroelectric layer. In this case the system breaks into multiple domains with opposite sign of the polarization normal to the interface so the average bound charge at the surface vanishes and the electric field in the ferroelectric layer is greatly reduced. This mechanism does not need for the participation of any material outside the ferroelectric film, but macroscopic models and first-principles simulations show that the formation of domains can actually be assisted or facilitated by the other material across the interface, either if it is a metallic electrode [55] or a highly polarizable material [56]. Although the overall neutrality of the surface or interface of the ferroelectric reduces very significantly the electric fields inside the domains (they should decay rapidly at the center of each domain), stray fields still contribute to the energy balance that ultimately determines the domain structure. In a polydomain structure as the one in Fig. 1.9(a) electric fields are confined to a very small region near the interface and their magnitude decay exponentially over a length-scale comparable to the domain width w [56]. The electrostatic energy of such structure thus increases with the domain size as Felec ∝ wP 2 . (1.23) Minimization of the electrostatic energy is favored by the reduction of the domains size, however the size of the domains of polarization is a consequence of the balance between the minimization of the electrostatic energy of the system, which tend to decrease the 24 Chapter 1. Ferroelectric thin films Figure 1.9: Schematic representation of typical domain arrangements in ferroelectric thin films. (a) 180◦ (Kittel) and (b) closure (Landau-Lifshitz) domains. (c) Effect of the electrostriction in closure domains. The dashed line represents on exaggerated scale the volume which would be occupied by the domain of closure if the constrain exerted by the rest of the crystal were removed. Domains of closure were thought unlikely to occur in ferroelectrics due to the elastic penalty associated with the large electrostriction in typical ferroelectrics. lateral size of domains, and the domain wall energy, which tend to increase it. The domain wall energy has in turn several contributions. Firstly at the domain wall, the structure of the ferroelectric is microscopically different from its bulk ground state and thus the internal energy density at those regions is larger. Secondly as a consequence of the different dipoles orientation when passing through the domain wall, dipole-dipole interaction is modified. Finally the polarization is strongly coupled with strain thus, either if the polarization switching across the domain wall occurs via a reduction of the polarization as we approach the wall or via rotation of the polarization, formation of a domain wall is associated to a strain field. As a result of all these factors a domain wall has an energy cost in the form of an energy per unit area of the wall σW . The associated energy, thus scales with the domain wall density as t , (1.24) w where t is the thickness of the ferroelectric film. The optimum balance for a given thickness is obtained minimizing Felec + FW , yielding FW ∝ σW w∝ √ t. (1.25) This formula, stating that as the thickness of the film reduces, so does the lateral size of the domains, is know as the Kittel relation. This formula was first obtained in the context of ferromagnetic materials, for which the theory of domain structures was first developed [57, 58, 59], and it has been found to be valid, also for ferroelectric materials, over a remarkably wide range of sizes [60]. Although the theory for domain structures for ferroelectrics is formally the same as the one developed for ferromagnets, the different physical origin of both phenomena 1.3. Ferroelectric thin films 25 leads to significant differences between domains structures in these two types of materials. In ferromagnets the exchange energy (which favors parallel alignment of spins) and the magnetocrystaline energy (analogous to the short-range interactions and the polarization-strain coupling, favoring sharp domain wall and hindering spin rotations) is usually dominated by the former and magnetic domain walls usually consist of a gradual rotation of spins over lengths of several nanometers (Bloch-type domain wall). Conversely, in ferroelectric materials – but also in some ferromagnets like cobalt – the coupling of the polarization (magnetization in ferromagnets) with the strain is much larger, and atomically sharp domain walls where polarization switch occurs over a few unit cells, are observed in these materials. This is also favored by the anisotropy of dipole-dipole interaction, favoring parallel alignment along the polarization axis but antiparallel in the perpendicular direction. First principles simulations on either bulk [61] or in thin films [55, 62] find that in typical perovskite ferroelectrics the polarization flips over a single unit cell. Not only the domain wall in ferroelectric materials differ from that typically observed in ferromagnets, the domain morphology and arrangement itself presents dissimilarities. Domain structures closing the magnetic flux have been observed for a long time in ferromagnetic materials [57, 58, 59]. In these structures, depicted schematically in Fig, 1.9(b), the normal component of the magnetization in always continuous across the domain walls and no poles are formed anywhere in the sample. Analogously closure domains in ferroelectric materials would minimize the electrostatic energy preventing the accumulation of bound charges. Nevertheless this kind of domain structure, usually referred as “Landau-Lifshitz domains”, were thought to be unlikely to form in ferroelectric materials due to the very large crystalline anisotropy that makes polarization rotation difficult: the polarization in ferroelectric materials is strongly coupled with strain, thus such domain would cause large stresses, as schematically depicted in Fig, 1.9(c). The unlikeness of closure domains is not due to the absence of aa-phases or to an intrinsic difficulty of polarization rotation, but more to the electrostriction, that imposes a great penalty in terms of elastic energy. Interestingly, recent theoretical works pointed to the formation of domains of closure in nanometric ferroelectric capacitors (see Chapter 5 and references therein) nanodots and nanorods [63, 64]; and other nanometric structures [65]. The theoretical predictions have been recently confirmed by the first experimental observations of such structures in PZT [66] and BiFeO3 [67] films. Some author also interpret Landau-Lifshitz domains in ferroelectric films as mixed “Bloch-Ising-Néel” domains, in analogy with domains in ferromagnets where the polarization rotates gradually [68]. Recent discoveries of exotic phenomena intrinsic to domain walls open new routes for the development of new functionalities exploiting the properties of these structures [2]. Examples of such phenomena are the conductivity observed in domain walls in BiFeO3 [10] and PZT [69] thin films, or the possibly polar ferroelastic domain walls in CaTiO3 [70] or SrTiO3 [30]. 26 Chapter 1. Ferroelectric thin films Eletrostatic coupling in superlattices Superlattices are artificially layered structures grown in an attempt to combine or tune properties of different materials. These seemingly simple systems have been found to display a rich spectrum of functionalities arising from complex interaction between mechanical and electrical boundary conditions, and the coupling of structural instabilities in the reduced symmetry environment of the interfaces [2, 46]. A notable type of superlattices are those consisting of ferroelectric films separated by paraelectric or incipient ferroelectric slabs. In these systems the development of depolarizaing fields is typically avoided adopting a a uniform component of the out-of-plane polarization throughout the structure. The continuity of the polarization is achieved at the cost of poling the paraelectric material and reducing the spontaneous polarization of the ferroelectric. In the most simple cases, the value of the polarization will be determined by the competition between the ferroelectric willing to polarize and the paraelectric opposing, the volume fraction of each material and the mechanical boundary conditions [71]. In some cases interfacial-intrinsic effects might play a significant role, like the in case of improper ferroelectricity observed in short-period PbTiO3 /SrTiO3 superlattices [19, 15], which behavior departs from that predicted by electrostatic coupling models. The improper ferroelectricity in this structure arises a consequence of a coupling between polar instabilities and AFD modes which is not present in the parent materials. In more complex systems, like tricolor superlattices, the inversion symmetry breaking have been proposed to lead to a built-in bias that would produce a self-poling of the heterostructure [72]. 1.4 Convergence of experiments and theoretical methods This is a particularly exciting time for nanoscale material science, as the experimental advances in materials preparation and characterization have come together with great progress in theoretical modeling of ferroelectrics, and both theorists and experimentalists can finally work on the same length and time scales. This allows real time feedback between theory and experiment, with new discoveries now routinely made both in the laboratory and on the computer. The rapid evolution in the atomistic modeling of materials, driven by the fast and steady increase of the computational power, the important progresses in the implementation of more efficient algorithms and the development of more and more accurate theoretical models, allows today the simulation of realistic systems, which can be often directly compared with actual samples. Computationally demanding first-principles simulations can today be used in systems large enough to investigate the complex physical processes that takes place at interfaces, isolated nanoparticles or very complicated crystal structures in bulk samples. Relevant degrees of freedom can be extracted and parametrized from first-principles calculations that are then introduced in model Hamiltonian or shell model methods. Reducing the number of degrees of freedom extends the size and time scales of the simulated system. These methods have also be a great importance to bridge 1.4. Convergence of experiments and theoretical methods 27 Figure 1.10: Sketch with the different length and time scales affordable with the variety of theoretical schemes typically discussed in the literature. Arrows indicate the interconnection between the methods. First-principles methods with atomic resolution (represented by the balls and sticks cartoon), feed second-principles models where only some degrees of freedom are considered (for instance, the soft mode in every unit cell, represented by the arrows or the springs in the cartoons). Parameters for the phenomenological Devonshire-Ginzburg-Landau methods can be determined from atomistic methods. The arrows in red stress the interconnection between experiments and theories at the different levels. the atomic magnitudes with the continuum models like the Devonshire-Ginzburg-Landau theory. On the experimental side, many groups are today capable of routinely grow singlecrystalline thin films with atomic control. The key for such achievement is the steady improvement of epitaxial growth techniques [73]. Traditionally, sputtering and pulsed laser deposition (PLD) were used for the growth of oxide thin films. These techniques 28 Chapter 1. Ferroelectric thin films consist in ejecting the component materials from solid source targets (typically a ceramic of the material one wants to grow in thin film) that then deposit on the free surface of a substrate. In the first case a high voltage is applied between the target (cathode) and the substrate (anode), the gas between the electrodes get ionized and the plasma bombards the target ejecting the source material. The ejected atoms are then transfered to the substrate. In the case of PLD, a high energy laser beam is used to ablate the targets instead of a plasma. The ejected material is transfered in gas phase (forming a “plume” emerging from the sources) to the substrate. Part of the success of both techniques has been the availability high-quality substrates with atomically smooth surfaces that facilitate the high-quality, defect-free deposition of the films. An alternative technique for the growth of thin films is the molecular beam epitaxy. Here, instead of ceramic targets, the sources are evaporated beams of the constituent atomic elements of the film. The process takes place in vacuum, not allowing the use of background atmospheres (in contrast with previous techniques), but in turn, this allows the use of reflection high-energy electron diffraction (RHEED) to monitor the growth of the film. The use of a real-time characterization techniques of the free surface of the sample during growth process opened up the ability to have submonolayer precision during film deposition. This fundamental achievement allows complete control over the growth of the interfaces in heterostructures. Characterization techniques have also undergone great improvements. Different varieties of atomic force microscopy (AFM) methods permit the sampling of various properties of thin films: from the topography of the surface (AFM itself) to the magnetic properties of the film (magnetic force microscopy, MFM). Particularly relevant in the case of ferroelectric thin films is the piezo-force microscopy (PFM) that allows to test the ferroelectricity of samples measuring its piezoelectric response upon applying an electric voltage between the AFM tip and the film. This technique is able to perform characterizations of either the overall film by the deposition of a top electrode or local measurements in free surfaces. The later case is specially interesting for the study of domains walls, allowing to obtain in-plane and out-of-plane piezoelectric responses (from which local orientation of the polarization can be inferred) or local hysteresis loops. Recently, great advances have been achieved in transmission electron microscopy (TEM) imaging as well. The recent implementation of spherical aberration correction in TEM improved the resolution of the TEM experiments from the Raleigh limit (typically around 1 Å) to the picometer range[74], allowing great precision in the measurement of inter-atomic distances and to extract relevant physical magnitudes with atomic resolution. Local polarization orientation, for instance can be extracted just from the relative displacements of the atoms. This technique can be combined with others, like electronenergy loss spectroscopy (EELS) capable of measuring atomic composition, chemical bonding properties, and electronic structure properties of individual atoms. However, very often TEM and associated techniques provides such amount of information that understanding the results is generally not straightforward and only possible through the comparison with extensive quantum-mechanical computer calculations. Pictures in Fig. 1.11 are a good example of the current situation of the research 1.5. References 29 of oxide thin films. This figure illustrate an ongoing project aiming to characterize the properties of PbTiO3 /SrTiO3 superlattices. Fig. 1.11(a) and (b) are TEM images of actual samples being grown and investigated by P. Zubko and coworkers at the University of Geneva. Fig. 1.11(c), on the other hand, is the relaxed structure of exactly the same system in a polydomain phase, as obtained by means of a first-principles simulation. This research, that is discussed in Chapter 6, is benefiting from a continuous interaction between experimental and theoretical groups that is being determinant for the understanding of the physical properties of this heterostructure. Figure 1.11: Comparison between (a, b) an actual image, obtained by transmission electron microscopy (TEM), of a PbTiO3 /SrTiO3 superlattice and (c) a real first-principles simulation of the same system. (TEM images courtesy of A. Torres-Pardo, from Université Paris Sud.) 1.5 References In this Chapter we have tried to provide a very brief review of the basic physics of ferroelectric materials as well as of the state of the art of this research field as far as we are concerned, aiming to provide in every case the appropriated references. However, all the topics discussed in this Chapter have been thoroughly reviewed before and much more detailed analysis can be found in the following works and references therein: 30 Chapter 1. Ferroelectric thin films • K. M. Rabe, C. H. Ahn, and J.-M. Triscone, editors, Physics of Ferroelectrics: A Modern Perspective. Springer-Verlag, Berlin Heidelberg, 2007 • Ph. Ghosez and J. Junquera. Handbook of theoretical and computational nanotechnology, vol. 7, ch. 134. American Scientific Publishers, 2006. • C. Lichtensteiger, P. Zubko, M. Stengel, P. Aguado-Puente, J.-M Triscone and J. Junquera, Ferroelectricity in ultrathin film capacitors. In G. Pacchioni and S. Valera, editors, Oxide ultrathin films: science and technology. John Wiley & Sons, 2011. Chapter 2 Methodology 2.1 Introduction The aim of this work is the theoretical study of screening properties in nanometric ferroelectric devices, systems where interfaces between ferroelectric and non ferroelectric materials play a key role. Overall properties of such systems are the result of the combination of intrinsic bulk properties of the materials composing the device with properties specific to the interfaces. In most of the systems we are interested in, which usually display a planar geometry, the region of interest is only a few nanometers thick, but the system is extended in the plane. Take for instance a typical ferroelectric thin film sample, the ferroelectric layer is only a few atomic monolayers thick, but the area of the device can be as large as 1 cm2 and in practice, given the in-plane to out-of-plane dimensions ratio, can be assumed to extend to infinity in the plane. This is a complicated situation since we want to perform simulations with atomic detail – to capture the subtle physics of the interface – in macroscopically large systems. We will see throughout this Chapter how these difficulties can be overcome. At the atomic scale classical continuum models of condensed matter are no longer valid, its explicit atomic nature must be taken into account and laws of quantum mechanics apply. Methods based exclusively on the equations of quantum mechanics and electromagnetism, not making use of any parameter fitted to experimental results, are called first-principles methods. These methods provide, in principle, an unbiased probe to study properties of condensed matter systems in conditions difficult or impossible to achieve in a laboratory and allow to isolate different contributions from the various effects. 2.2 Overview of approximations Properties of materials at the nanometric scale are obtained studying the behavior of their basic components at the atomic level, i.e. nuclei and electrons. At this scale, according to quantum mechanics the expected value of any physical quantity can be 31 32 Chapter 2. Methodology obtained theoretically if one knows the wave function Φ for all the particles of the system. This object, in turn, is the solution of the Schrödinger equation of the system, that assuming a time-independent problem (i.e. that the potential entering the Hamiltonian of the system does not depend on time) is the following H(R, r)Φ(R, r) = EΦ(R, r), (2.1) where H is the Hamiltonian of the system, which is a function of the position of all nuclei, {R}, and electrons, {r}; and E is the total energy of the system. The Hamiltonian of a system of interacting nuclei and electrons can be written as (unless otherwise stated throughout the chapter we will use atomic units, i.e. e = h̄ = me = 1) H(R, r) = TN (R) + VN N (R) + Te (r) + Vee (r) + VN e (R, r) = (2.2) P P P P 2 2 Z Z Z 1 1 1 1 ∂ ∂ 1 I I J I,i |RI −ri | . I MI ∂R2 + 2 I6=J |RI −RJ | − 2 i ∂r 2 + 2 i6=j |ri −rj | − 1P = −2 I i In Eq. (2.2) TN and Tn are, respectively, the kinetic energy of nuclei and electrons; and VN N , Vee and VN e are, respectively, the nucleus-nucleus, electron-electron and nucleuselectron electrostatic interactions. The latter is the only attractive interaction among all of them and thus can be thought as the “glue” of condensed matter systems. Solution of Eq. (2.1) would provide all possible information about the studied system, however its complexity makes it impossible to solve but for the simplest molecules. Several approximations must be done to transform this into a solvable problem in practical systems: • Born-Oppenheimer approximation allows to decouple the movement of electrons and nuclei. • Density functional theory provide a very efficient method to solve the electronic problem substituting the electronic wave function by the electronic charge density as the fundamental variable of the problem. This formalism is exact but needs some approximation to the exchange-correlation energy functional. • Using pseudopotentials we can get rid of a large number of chemically inert electrons and avoid sharp oscillations of the wave functions near the core region, reducing the number of required basis functions. • Periodic boundary conditions allows the simulation of infinite periodic crystals reducing the problem to calculation on a periodically repeated simulation box. By means of the supercell technique also non-periodic systems can be studied within these boundary conditions. • Calculation of physical magnitudes that require integrations over the first Brillouin zone are typically performed by means of a finite sampling of reciprocal space. 2.3. Born-Oppenheimer approximation 33 • Expanding one-electron wave functions into a linear combination of basis functions our search for an unknown function transforms into a search for a set of coefficients. It is beyond the scope of this work to provide a detailed derivation of all these approximations, we will instead try to provide a concise overview of how we take advantage of them to solve our problem. We will emphasize their strong and weak points trying to clarify their applicability limits. Extensive reviews of all these approximations can be found in the references provided in Sec. 2.9. 2.3 Born-Oppenheimer approximation The very first approximation we use to transform Eq. (2.1) into a solvable problem is the Born-Oppenheimer or adiabatic approximation. Taking into account that nuclei mass is thousands of times larger than electrons mass – the mass ratio between an electron and a proton is comparable to that of a human baby and an adult elephant –, we can assume that the velocity of electrons would be much larger than that of the nuclei (typical velocities of nuclei and electrons are of the order of 103 m/s and 106 m/s respectively). For this reason the nuclei kinetic energy TN in Eq. (2.2) can be considered as a perturbation of an electronic Hamiltonian He (r; R) = Te (r) + Vee (r) + VN e (r; R) + VN N (R). (2.3) where nuclear positions enter as parameters [this is denoted in Eq.(2.3) separating parameters and variable with a semicolon] and are kept constant while solving the electronic problem. Notice that now in Eq. (2.3) VN e (R, r) is the energy of the electrons in a fixed potential created by nuclei and VN N (R) is just a constant. Now, after solving the electronic Schrödinger equation He (r; R)Ψ(r) = Ee Ψ(r), (2.4) its eigenvalues Ee act as the potential energy for the nuclei, which movement can be usually solved using classical mechanics. The solution of the electronic Schrödinger equation provides the quantum description of electronic properties for any given ionic positions. Moreover, forces and stresses can be obtained which can be used to perform structural relaxations molecular dynamics simulations or phonon analysis. This way the Born-Oppenheimer approximation decouples nuclei and electrons movement greatly simplifying the problem, but allowing, at the same time, for efficient characterization of both electronic an structural properties without loss of accuracy. 2.4 Density functional theory Solving Eq. (2.4) for a set of interacting electrons requires searching for a very complex object, the many body electronic wave function Ψ(r), a function of 3Ne coupled 34 Chapter 2. Methodology variables (where Ne is the number of electrons in the system), which – since electrons are fermions – has to be antisymmetric with respect to an interchange of any pair of electrons. This is still an impossible task in most practical cases. Most methods in quantum chemistry approach this issue constructing the all-electron wave function as a combination of Slater determinants, which in turn are build from one-particle wave functions. These methods can provide extremely precise results incorporating more and more configurational determinants in the expansion, but the computational cost scales extremely fast and restrict their usefulness to molecular systems or small atomic clusters. Density functional theory (DFT) provide an alternative and elegant approach to the electronic problem. DFT was born in the 1960’s from the works of Hohenberg and Kohn [75] and Kohn and Sham [76]. In the first paper, Hohenberg and Kohn proved that the external potential vext (r) in the electronic Hamiltonian (the electrostatic potential created by the nuclei, for instance) is univocally determined by the ground state electronic density ρ0 (r). It trivially follows that the whole electronic Hamiltonian, and thus also the ground state energy and wave function, are defined by the ground state electronic density. Consequently an energy functional of the density can be defined and the minimization of such functional would provide the ground state density of the system for a given external potential. Using the groundbreaking work by Hohenberg and Kohn [75] we can reformulate the problem of searching for the solution of the many-body Schrödinger equation in terms of the electronic density, which is a function of just three variables. However, although the ground state electronic charge density is in principle sufficient to obtain any property of a given material, the paper by Hohenberg and Kohn doesn’t provide any clue about how to extract such properties from it. At this point is where the work by Kohn and Sham [76] comes into play providing precisely a practical method to take advantage of the density functional theory. The approach consists in replacing the many-body problem of interacting electrons by a fictitious system of non interacting particles moving in an effective potential. The electronic charge density of this auxiliary system can be calculated from the one-electron wave functions as ρ(r) = occ X i |ψi (r)|2 . (2.5) If we build the system of non-interacting particles so that their electronic charge density equals the real one, the energy functional of the real system can be written in terms of the one-electron auxiliary functions and the electronic density as Z 1X 1 ρ(r)ρ(r 0 ) 2 EKS [ψi ] = − < ψi |∇ |ψi > + drdr 0 2 2 |r − r 0 | i Z +Exc [ρ(r)] + vext (r)ρ(r)dr + EN N (2.6) where the first term is the kinetic energy of a collection of non interacting electrons. The 35 2.4. Density functional theory second is the Coulomb electrostatic energy, which in the context of quantum mechanics of condensed matter systems is also referred as Hartree term. The third term in the equation is the so called exchange-correlation term which contains the difference between the kinetic energy of the real electrons and the non interacting particles as well as any electron-electron interaction beyond the classic Coulomb repulsion. The fourth term is the potential energy of the electrons on the external potential (usually the potential created by the nuclei) and the last term is the nucleus-nucleus electrostatic energy. The variational problem on the electronic density transforms into the variational problem over the set of one-electron functions. The minimization of the energy functional of Eq. (2.6) should give rise to the set of {ψi } which through Eq. (2.5) would lead to the ground state electronic density of the real system of interacting electrons. This minimization is performed under the constraint of orthonormalization of the one-electron wave functions < ψi |ψj >= δij , and gives rise to the following Schrödinger-like equations 1 2 Heff ψi (r) = − ∇ + veff (r) ψi (r) = Ei ψi (r), 2 (2.7) (2.8) where the effective potential takes the form Z veff (r) = ρ(r 0 ) dr 0 + vxc (r) + vext (r). |r − r 0 | (2.9) The exchange-correlation potential is defined as vxc (r) = δExc [ρ(r)] . δρ(r) (2.10) Equations (2.5),(2.8) and (2.9) constitute the so called Kohn and Sham equations, which when solved provide the one-electron eigenstates which electronic density coincide with the ground state density of the actual system. In practice this problem is solved selfconsistently: equations are solved for a trial density ρin (r) (coming from a trial set of {ψi (r)}) and a new density ρout (r) is obtained as an output. The input and output densities are compared and a new input density is created as a mix between ρin (r) and ρout (r). The procedure is repeated until self consistency is achieved and ρout (r) = ρin (r). At this point several aspects of the density functional theory should be highlighted. Firstly, leaving aside the Born-Oppenheimer approximation on top of which most theoretical methods for condensed matter physics are build, the DFT is an exact theory. The density computed with the one-electron wave functions obtained from the Kohn-Sham equations would be equal to the actual ground state electronic density and any ground state physical property of the system could be derived from it. This is true as long as the energy functional of Eq. (2.6) is the exact one. Unfortunately the exchange-correlation term is not known so in practice approximations to this term must be made. 36 2.4.1 Chapter 2. Methodology Exchange and correlation functional As we have just remarked, the formalism of the density functional theory is exact but the form of the universal exchange-correlation energy functional to be used is unknown and, in practice, it must be approximated. In principle Exc [ρ(r)] depends on the charge density in every point of space. However we can assume that for slow varying charge densities, as in metals, this functional could be approximated by a function of the density at each point. This is the local density approximation (LDA). Within this approximation the exchange and correlation energy at a given point is that of an homogeneous electron gas, hom xc , with the same electronic density of the system at that point LDA Exc [ρ(r)] Z = hom ρ(r) ρ(r)dr. xc (2.11) The exchange-correlation potential of an homogeneous gas can be calculated very precisely by means of Quantum Montecarlo simulations [77]. This approximation can be improved including in the functional terms depending on the gradients of the charge density. Under this approximation, named generalized gradient gpproximation (GGA), the exchange-correlation term is still a “semi-local” function and not a functional: GGA Exc [ρ(r)] Z = xc ρ(r), |∇ρ(r)|, ... ρ(r)dr. (2.12) More precise approximations exist that go beyond these two examples. One example is the hybrid functionals which typically consist of a linear combination of one of the previous local functionals (LDA or GGA) with the Hartree-Fock exact exchange calculated from the one-electron wave functions. Of course, non local approximations like these do not come cheap and comparatively have a great computational cost. Nevertheless, some of these hybrid functionals, in particular the B1-WC [78], have been proved to provide good ground state electronic and atomic structure and would be very reasonable options to go beyond the LDA for some of the results of the present work. Despite being crude approximations, the local LDA and GGA functional are widely used due to their efficiency and remarkably performance. In many cases they have been probed to be surprisingly reliable, specially for the study of structural properties (see Table 2.1). However they also have some limitations that should be noticed. The most serious error is the electronic band gap estimation, for which values of around 50% of the experimental gap are typically obtained. Usually in calculations of bulk materials this limitation doesn’t have any further consequence but in Chapter 3 we will see how this can lead to unphysical results in the case of ferroelectric capacitors and we will provide the correct procedure to detect such pathological behaviors. Besides the approximation required to the exchange-correlation functional some further approximations help to provide a practical implementation of the density functional theory, allowing for very efficient yet precise and reliable quantum simulations of con- 37 2.5. Pseudopotentials Table 2.1: Typical errors introduced in the computation of structural, energetic and electronic properties by LDA and GGA aproximations to the exchange-correlation functional. For comparative studies see [79], [80] and [81]. Lattice constants Bulk modulus Cohesion energy Band gap LDA -1% – -3% +10% – +40% +15% -50% GGA +1% -20% – +10% -5% -50% densed matter systems. In the following sections we will discuss some of the most common and important of these approximations. 2.5 Pseudopotentials Taking into account their participation in the bonding formation and chemical processes, electrons in an atom can be classified into core and valence electrons. The core electrons are inner electrons with deeper energy levels and are extremely localized close to the nucleus. They do not overlap with orbitals from neighboring atoms and thus they are essentially insensitive to the chemical environment. In fact most of the physical and chemical properties of a condensed matter system can be perfectly explained in terms of the valence electrons and the main effect of core electrons is to screen the nucleus potential felt by the former. Besides increasing unnecessarily the number of electrons in the system (and thus the number of Kohn-Sham eigenfunctions to compute) the core electrons introduce another undesirable feature: exclusion principle forces the orthogonality between core and valence wave functions and this causes strong oscillations of the latter in the inner region of the electronic cloud. Many DFT methods expand the Kohn-Sham eigenfunctions in plane waves or make use of real space grids (see Sec. 2.8). In that case the description of valence states require the use of a huge number of basis functions or very fine grids to accurately reproduce the strong oscillations of the wave functions. Pseudopotentials were developed to get rid of these issues. The pseudopotential approximation is carried out in two steps: (i) since core electrons are not affected by chemical environment they can be considered as frozen into their isolated atom configuration (frozen-core approximation), and then (ii) the frozen core electrons together with the nucleus potential can be substituted by a screened and smoothed fictitious potential, the pseudopotential. Once core wave functions have been removed and nucleus potential screened, valence wave functions are allowed to vary smoothly in the inner regions. In practice a pseudopotential generation starts with an all-electron simulation of an isolated atom in a reference electronic configuration. The nucleus potential together with the core electrons are then substituted by the pseudopotential, forcing the valence 38 Chapter 2. Methodology wave functions to coincide with the valence wave functions of the all-electron atom in the outer region (in practice a cutoff radius is used). The pseudopotential is fitted to reproduce not only the valence wave functions but also the eigenvalues of the reference all-electron simulation. A good pseudopotential is expected to have two qualities. The pseudopotential is generated for a reference electronic configuration, but to be useful it must be transferable to different chemical environments, being flexible enough to reproduce reliably the results one would obtain in an all electron simulation. At the same time it is desired to be sufficiently smooth so the number of plane waves and/or grid points can be reduced. These two qualities however are competing, the more the pseudo-wave functions resemble the real ones the more transferable and less smooth the pseudopotential is. At the end of the day, and as in any other approximation made, one must obtain a suitable balance between reliability and feasibility. Sometimes the division in core or valence states is not as strict as stated before and there is a significant overlap between core and valence change densities. The so called semi-core states are chemically inert but introduce some exchange-correlation interactions with valence electrons that must be taken into account either including these states in the valence set or using non-linear core corrections [82]. Thanks to the pseudopotential approximation the number of electrons in the simulation is greatly reduced and shorter basis sets can be used while keeping a good description of the valence wave functions, decreasing enormously the number of variables of our problem. 2.6 Periodic boundary conditions In the study of periodic solids it is usual to consider Born-von Karman periodic boundary conditions. Within these boundary conditions a periodic lattice is defined as an infinite repetition of a given unit cell in every direction. Any observable of the system, and of course the effective potential, must be periodic, or in other words it must be invariant with respect to a translation of a lattice vector a, veff (r) = veff (r + a). (2.13) For such infinite periodic systems, the Bloch theorem states that the eigenfunctions of the one-electron Hamiltonian in a periodic potential may be written as the product of a plane wave envelope function and a Bloch function un,k (r) that has the same periodicity as the lattice [83] ψn,k (r) = eik·r un,k (r), (2.14) un,k (r) = un,k (r + a). (2.15) where 2.6. Periodic boundary conditions 39 The one-electron Kohn-Sham wave functions (ψi in previous Sections, ψn,k here) can thus be classified in terms of a wave vector k inside the first Brillouin zone and a band index n. A crystal is precisely a material which structure consists of a unit cell periodically repeated along the three dimensions. Although the ideal perfectly periodic and infinite crystal does not exist in Nature, many properties of materials depend mostly on the bulk and not on the surfaces (there are notable exceptions to this rule though, and this work is mostly concern with them, but we shall see in a moment that the implementation of periodic boundary conditions doesn’t preclude at all the study of those phenomena). Thus, periodic boundary conditions are the natural choice for the simulation of bulk crystalline materials and are the boundary conditions implemented in most DFT-based methods for the study of solid state systems. Figure 2.1: Schematic view of appropiate supercells for the simulations under periodic boundary conditions of a bulk crystal (a), a superlattice (b), an isolated cluster (c) and a slab (d). Despite being specially suited for the study of bulk systems [Fig. 2.1(a)], more complex structures can be efficiently and reliably simulated within periodic boundary 40 Chapter 2. Methodology conditions making use of the supercell technique [84]. This technique consists in building a simulation box, containing more than just a primitive unit cell of a given material, that is repeated periodically over all space. This technique is regularly applied for the simulation of: • Complex structures within bulk crystals, like domains (of polarization, magnetic, elastic, etc.). In this case several unit cells of the material are included in the simulation box so different arrangements of the order parameter are allowed. • Superlattices can also be simulated using supercells [Fig. 2.1(b)]. These are structures consisting of a periodic stacking along one dimension of alternating layers of different materials. Capacitors, which are one of the systems that constitutes the main subject of the present thesis, might be considered as a particular case of superlattice. A real thin film capacitor consists of an insulating layer between relatively thick (typically assumed to be semi-infinite) metallic electrodes. In practice however, due to the periodic boundary conditions, what we are simulating is an infinite series of alternating metallic and insulating layers. Thus, Figure 2.1(b) might also depict this case, with the darker atoms corresponding to the metallic region and the lighter ones to the insulator/ferroelectric. To mimic the properties of a realistic capacitor with semi-infinite electrodes the metallic region included in the simulation box should be thick enough to avoid interactions of the two periodically repeated interfaces. For this particular kind of systems it is worth remarking that periodic boundary conditions affect any measurable property of the system, and in particular the electrostatic potential must obey the periodicity of the supercell. This is particularly important for the simulation of capacitors since it is equivalent to assume short-circuit electrostatic boundary conditions between the electrodes. Recently strategies to performed constrained electric field E [85, 86] and electric displacement D [87, 52] calculations under periodic boundary conditions have been implemented, allowing to overcome this limitation and to perform simulations under virtually any electrostatic boundary condition. • Zero-dimensional systems like molecules or nanoparticles can be simulated with this technique as well, embedding the object in vacuum inside a large simulation box, as in Fig. 2.1(c). • For the simulation of slabs and surfaces [systems periodic only along two dimensions, see Fig. 2.1(d)] a vacuum region should be included in the simulation box to avoid spurious interactions between periodic images. Every time supercell technique is used, a careful convergence study of the dependence of the properties of the system with respect to the supercell size should be carried out. 41 2.7. Brillouin zone sampling and electronic temperature 2.7 Brillouin zone sampling and electronic temperature We have seen in the previous section that as a consequence of the periodic boundary conditions eigenfunction of the one-particle Kohn-Sham equations can be written as Bloch states, characterized by the quantum number k and the band index n. Many physical properties of condensed matter systems do not depend on one particular eigenstate, but on the integrated contribution of all of them. The obvious example is the electronic charge density, that is calculated as the sum over bands of an integral over the first Brillouin zone XZ |ψn,k (r)|2 fn (k)dk, (2.16) ρ(r) = n k∈1BZ where 1BZ denotes the first Brillouin zone and fn (k) is the occupation function. At zero temperature energy levels are filled following the Aufbau rule and accordingly fn (k) is a step function where one-electron levels can only have an occupation of two (assuming spin degeneracy) or zero electrons. In an infinite system, as those we are dealing with, the integral in Eq. (2.16) implies a continuous sum over an infinite number of k-points. Obviously such infinite sum is impossible to treat in practice. The usual approach to compute physical magnitudes that require integration over the first Brillouin zone is to replace the integral by a discrete sum over a finite selection of k-points ρ(r) = X X n k∈1BZ |ψn,k (r)|2 wk fn (k), (2.17) where wk are the weight factors of k-points that depend on the way the sampling is performed. Fortunately eigenfunctions change smoothly with k so it is possible to obtain a good representation of the continuum of states with a finite sample over an appropriate grid of k-points. Several schemes have been proposed in the past for efficient samplings of the Brillouin zone [88, 89] but today the most widely used is the one proposed by Monkhorst and Pack [90]. Within this method a number of divisions Ni along each reciprocal lattice vector of the simulation box bi is chosen. Then the sampled k-points are obtained as k = q1 b 1 + q2 b 2 + q3 b 3 , (2.18) 2j − Ni − 1 , 2Ni (2.19) where qi = j = 1, 2, ..., Ni . Very often the study of a particular device involves the comparison of different calculations performed on different simulation boxes (or supercells). In those cases, and specially in metallic systems, it is strongly advisable to make sure that the density (and not the total number) of k-points used for the discretization of the reciprocal space is the same in all calculations. 42 Chapter 2. Methodology Table 2.2: Convergence with respect to the Monkhorst-Pack mesh of structural parameters and energy difference between tetragonal and cubic phases of bulk BaTiO3 . ∆zα is the off-center displacement of atom α in units of the lattice vector c. (For a 2 × 2 × 2 Monkhorst-Pack mesh the cubic phase is found as ground state.) MP mesh 2×2×2 4×4×4 6×6×6 8×8×8 Experiment a (Å ) 3.947 3.942 3.938 3.939 3.986 c (Å ) 3.947 3.974 3.997 3.991 4.026 c/a ∆zT i ∆zO1 ∆zO2 1.000 1.008 1.015 1.013 1.010 0.000 0.012 0.016 0.015 0.015 0.000 -0.015 -0.022 -0.020 -0.023 0.000 -0.010 -0.015 -0.014 -0.016 ∆ (Etetra − Ecubic ) (meV) -3.41 -9.77 -10.86 How fine this sampling should be would strongly depends on the nature of our system and the property we are interested in. Metallic systems where many properties depend on a few states around the Fermi surface require finer grids than insulators in which the occupied states are well defined thanks to the presence of the band gap. Ferroelectric perovskites are exception to this rule, since despite being insulators they require fairly fine k-point mesh. For instance, in Table 2.2 structural and energetic properties of bulk BaTiO3 obtained with different Monkhorst-Pack samplings show that a mesh of at least 6 × 6 × 6 is required to achieve converged results [91]. In metallic systems a finite k-point sampling can lead to convergence problems as some states can cross the Fermi level during the course of the self-consistency process, leading to large oscillations of the electronic density. To avoid the use of huge samplings, mitigate the sensitivity with respect to the k-points, and improve convergence rate in metals, a smearing is often applied to the Fermi surface. This smearing is implemented introducing a smooth occupation distribution fn (k) = f (Enk ) in Eq. (2.17) (substituting the step function that would correspond to an occupation function at zero temperature). Typical choices for the occupation function are a Gaussian distribution [92] En,k − EF 1 fG (En,k ) = erfc , (2.20) 2 σ where erfc is the complementary error function, or Fermi-Dirac distribution fFD (En,k ) = 1 e(En,k −EF )/σ +1 , (2.21) where σ is the broadening energy parameter. A smooth occupation function leads to a partial population of the energy levels around the Fermi energy, improving performance during the simulation of metallic systems. The smearing parameter can be understood as a fictitious electronic temperature Te = σ/kB , but the minimization of the KohnSham energy functional only leads to the ground state electronic density for a system of 43 2.8. Basis sets electrons at zero temperature so, when a finite electronic temperature is used to improve the stability of a simulation it must be gradually reduced until convergence is achieved. 2.8 Basis sets Let’s go back to the Kohn-Sham Eqs. (2.5), (2.8) and (2.9). Equation (2.8) is a set of differential equations which solution is a set of functions ψi (r). This problem can be greatly simplified expanding the solutions as linear combinations of basis functions ψi (r) = X cij φj (r). (2.22) j With this trick Eq. (2.8) transforms into a set of algebraic equations, for which very efficient numerical methods are available. Essentially what we have just done is to replace the problem of solving Eq. (2.8) for a function in every point of space to solve it for a series of coefficients (a “few” complex numbers). Several types of basis functions can be used, each with its own advantages and disadvantages. Among all, most common methods implement one of the following: plane waves, atomic orbitals or atomic spheres. 2.8.1 Plane waves This basis emerges naturally from the periodic boundary conditions and the Bloch theorem. Since, as we have seen in Sec. 2.6, the solutions of the Kohn-Sham equations can be expressed as products of plane waves with periodic functions, decomposing ψn,k in a Fourier expansion provide intuitive understanding of solid physics in terms of the band structure. If Ω is the volume of the simulation box and G is a reciprocal lattice vector this expansion can be written as 1 X ψn,k (r) = √ Cn,k,G ei(k+G)r . Ω G (2.23) In principle previous sum involves an infinite number of plane waves, but in practice a cutoff is imposed to the maximum energy of the plane wave in the expansion. Plane waves as basis functions present several advantages. Firstly, they are asymptotically complete and, most importantly, the completeness of the basis is trivial to approach increasing the number of elements in the expansion. Being completely non localized they provide unbiased, homogeneous and isotropic description of the electronic structure of the system. Moreover they allow a trivial use of fast Fourier transform techniques for which extremely efficient subroutines are available simplifying the implementation of plane waves codes. Of course this approach has also some pitfalls. While being able to represent any function, they are at the same time not particularly well suited for any. Besides, their homogeneity turns into a disadvantage in simulations with supercells containing large 44 Chapter 2. Methodology vacuum regions, since plane waves extend over the whole space regardless of the presence or absence of material near a particular point. 2.8.2 Atomic orbitals This type of basis sets captures the essence of the atomic-like features of solids and molecules expanding the one-electron eigenfunctions in a set of functions centered on each atom of the system. This allows extremely efficient expansions, requiring, comparatively, a much smaller number of basis functions with respect to a plane wave calculation to obtain the same accuracy. Localized functions typically consist of a spherical harmonic Ylm times a radial function Rln (r) centered at an atomic position RI , d φInlm (r) = Rln (|r − RI |)Ylm (r − RI ), (2.24) d where r − RI is the direction vector. Different choices are possible for the radial function, either analytical or numerical functions have been implemented. Among the former, the most common choice are Gaussian functions [93] for their easy implementation, and Slater orbitals [94] due to their similarity with the actual shape of the wave functions of an isolated atom. Numerical atomic orbitals [95] on the other hand, are more difficult to implement due to the lack of analytic integrals, but are the most flexible and can be optimized for each particular element and chemical environment [96, 97]. Atomic orbitals methods can also take advantage of locality principle to implement order-N methods which computational cost scales linearly with the number of electrons of the system. In contrast to plane waves, which provide an intuitive vision of band structure, atomic orbitals are suitable tools for the analysis of bonding formation and hybridizations. They are specially suited to represent atomic wave functions and therefore they are much more efficient, typically requiring just a few dozens of basis functions to achieve an accuracy comparable to a calculation with several hundreds of plane waves [95]. Despite being able to achieve accuracies perfectly comparable to plane waves calculations, they are much harder to improve and there is not an easy recipe to do it systematically. Atomic basis sets are improved increasing their radial and angular flexibility [98]. Radial flexibility of basis functions is improved including more than one different radial functions for some selected orbitals. The number of radial functions of a given orbital is denoted by its ζ (Zeta) number. Radial flexibility is important for instance to reproduce correctly different ionization states of the atom, where the extension of the electronic cloud would depend on the greater or smaller inter-electronic repulsion. An extra shell corresponding to the first unoccupied angular momentum channel is usually added to polarize the most extended atomic valence orbitals, giving angular freedom to the valence electrons in order to improve the description of bond formation and hybridization. A basis set including, for instance, two radial functions per atomic orbital plus polarization functions is usually denoted as double-ζ plus polarization or DZP. The correct size (ζ) and polarization of a basis set can only be determine by means of tests. 2.9. References 45 It is already evident that a great cost in terms of human effort is the main drawback of the use of atomic orbitals as basis functions, and the price to pay if we want to take advantage of their great efficiency. 2.8.3 Atomic spheres This method combines the best of both previous worlds. Within this method, spheres centered at every atomic position are defined. Inside these spheres, atomic-like orbitals are used to expand the wave functions, while plane waves are used for the description of the wave functions in the interstitial regions. As in the case of plane waves, these basis sets are asymptotically complete but they converge faster with the number of basis functions and they are able to provide a good description of the electronic structure of real solids with rapidly varying atomic-like functions near the nuclei and smoothly varying functions between the atoms. The use of sharp functions in the atomic core regions make unnecessary the use of pseudopotentials, applying only the frozen-core approximation to avoid the calculation of the core levels. Their use is, however, limited by their difficult implementation and the computational cost, much larger than for the previously explained methods. Also, as they do not rely on the use of pseudopotentials and explicitly incorporate the core levels, the total energies obtained with these methods are usually huge, requiring very converged simulations when energy differences between different phases are being calculated. 2.9 References All the approximations described in this Chapter are discussed in great detail in many books and reviews. Some particularly good ones are: • R. M. Martin, Electronic Structure, Basic Theory and Practical Methods, Cambridge University Press (2004). • J, Kohanoff, Electronic Structure, Calculations for Solids and Molecules, Cambridge University Press (2006). • R. G. Parr and W. Yang, Density Functional Theory of atoms and molecules, Oxford University Press (1989). • M. C. Payne, M. P. Teter, D. C. Allan, T. A. Arias and J. D. Joannopoulos, Rev. Mod. Phys. 64, 1045 (1992). Chapter 3 Band alignment issues in the ab initio simulation of ferroelectric capacitors 3.1 Introduction As pointed out in the Introduction of this thesis, the outstanding degree of development achieved in the last years in thin film growth and characterization techniques has lead to the fabrication of many novel oxide-based metal-insulator heterostructures with a dizzying range of functionalities. Density functional theory (DFT) methods, either within the local density (LDA) or generalized gradient (GGA) approximation, have been an invaluable tool in achieving a fundamental understanding of this class of systems [99, 7, 21], particularly with recent developments which allow the application of finite electric fields to periodic solids or layered heterostructures [85, 100, 86, 87, 52]. However, since this domain of research is relatively new, it is important to identify, in addition to the virtues, also the limitations of DFT that are specific to metal/ferroelectric interfaces, and that when overlooked might lead to erroneous physical conclusions. For most practical applications, a capacitor must be insulating to direct current (DC); transmission of electrons via non-zero conductivity and/or direct tunneling (leakage) is generally an undesirable source of heating and power consumption. At the quantum mechanical level, the insulating properties of a capacitor are guaranteed by the presence of a dielectric film with a finite band gap at the Fermi level, where propagation of the metallic conduction electrons is forbidden. In the language of semiconductor physics, we can alternatively say that both Schottky barrier heights (SBH), respectively φn and φp for electrons and holes, need to be positive for the device to behave as a capacitor [see Fig. 3.1(a)]. (By convention we assume that, if the Fermi level of the metal lies in the gap, both φn and φp are positive.) If, on the contrary, either φp or φn is negative, injection of holes or electrons into the dielectric becomes energetically favorable and the device behaves instead as an Ohmic contact. Most importantly, at such a junction there is necessarily (at thermodynamic 47 48 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors (a) φn φp EF (d) (b) (c) (e) (f) EC EV (g) Figure 3.1: Schematic representation of the common band-alignment scenarios that can be found in short-circuited ferroelectric capacitors. Left panels (a,d,g) refer to unpolarized devices (this configuration is accessible experimentally by increasing the temperature above the Curie point, or in a first-principles calculation by imposing a mirror symmetry plane). Central panels (b,e) refer to thin-film capacitors in a polarized monodomain state (note the linear slope of the bands that is due to the depolarizing field). Right panels (c,f) refer to macroscopically thick capacitors where the depolarizing field is negligible (although there is a potential drop across the capacitor, the dotted lines in these panels) and the polarization converges to the bulk spontaneous value. The first row (a-c) pictures a hypothetical well-behaved system, where the Schottky barrier heights are positive at any polarization state. The second row (d-f) refers to a situation where the paraelectric configuration (d) is well-behaved, but the band alignment becomes pathological once the system goes ferroelectric (e-f). The third row (g) shows a capacitor that is pathological already in the paraelectric reference structure; in such a case, it is meaningless to analyze the ferroelectric state as the system is metallic throughout its thickness. EV and EC stand, respectively, for the valence band maximum and the conduction band minimum of the insulator. EF is the Fermi level of the metal. φn and φp represent, respectively, the n-type and p-type Schottky barriers. 3.1. Introduction 49 equilibrium) a spill-out of charge from the metal to the insulator, as the system reequilibrates the chemical potential of the free carriers on either side. Such intrinsic space charge induces metallicity (by intrinsic doping) in the dielectric film, and overall profoundly alters the electronic and structural properties of the interface. While in principle the charge spillage might be a real physical feature of a given system, there are several arguments that advise caution in the interpretation of DFT calculations where this effect is found. As we indicated in Sec. 2.4.1, the main limitation of the most widely used approximation to the exchange-correlation functional, namely the LDA and GGA, generally produce a severe underestimation of the fundamental band gap in insulators. This error directly propagates to the values of φp and φn that are extracted from a DFT calculation. In the best scenario, DFT yields values of φp and φn that are still positive. In such a case, it is commonly assumed that the interfacial charge density (which is a ground-state property) and, consequently, the associated dipole moment are well described by the theory, even if both φp and φn (an excitedstate property) are significantly smaller than the experimentally measured Schottky barrier heights. Then, a relatively simple quasiparticle correction to the band edges of the insulator is commonly used to correct φp and φn , and obtain a reliable estimate of the Schottky barrier heights (SBH) [101]. There are situations, however, where the DFT simulation yields a negative value of either φp or φn [see Fig.3.1(g) for the case where φn is negative in an unpolarizaed capacitor]. In such cases, as we mentioned before, there is a spill-out of charge carriers that populate (or deplete) the bands of the insulator. Obviously, the amount of spilledout charge directly depends on the DFT values of φp and φn (the more negative the SBH, the larger the number of states of the insulator that cross the Fermi level). While it is widely known that electronic excited states are not necessarily well described within the usual exchange-correlation approximations, the possible influence of these on some ground-state magnitudes is usually overlooked. In this case, negative values of φp and φn , which are likely to be an artifact of LDA or GGA, can directly affect the ground-state charge density, and potentially produce a number of unphysical features in the relaxed electronic and atomic structure of the capacitor. As we shall see in the following, in such a pathological regime the interface dipole is poorly described by the theory, and the physical properties of the dielectric film are strongly altered by the presence of space charge in the system. It is therefore crucial to clearly identify whether this scenario applies to a given interface, by performing an accurate analysis of the band alignment and of the distribution of the metallic carriers in the relaxed structure. Such an analysis is not entirely straightforward as the distinction between “nonpathological” and “patological” band alignment can be subtle in a DFT calculation. In capacitors with thicknesses of a few nanometers, quantum phenomena that can be disregarded in Schottky barrier measurements of macroscopic capacitors must be considered. The quantum nature of the electrons, for instance, implies that the metallic wave functions do penetrate in the insulator up to a distance from the interface, even in cases where both φp and φn are well positive. The evanescent tails of these Bloch states, which are exponentially damped with increasing distance from the interface, are commonly known 50 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors as “metal-induced gap states” (MIGS) [102]. Their presence is normal and should not raise any concern when detected in a calculation. In order to identify a pathological case it is therefore crucial to assess the physical nature of the charged carriers that diffuse into the dielectric film, i.e. whether they originate from MIGS (non-pathological) or from population/depletion of the bands of the insulator (pathological). A clear picture only emerges once one combines several postprocessing tools, as we shall explain in detail in the remainder of this Chapter. Properties of the physically meaningful charge transfers due to the MIGS are explored in Chapter 4 of this manuscript. The previous issues are general and apply not only to the Schottky barrier heights at metal/oxide junctions but to the band offsets at semiconductor/semiconductor and semiconductor/metal interfaces as well. However, the case of metal/perovskite oxide interfaces deserves special attention, as here the band-alignment issue appears to be particularly serious. Indeed, in most of these compounds the bottom of the conduction band and the top of the valence band have a marked localized orbital character (respectively, cation d and oxygen p), which makes the effects of the self-interaction error [103] particularly pernicious. Very often, it is so strong that the band lineup calculated from first-principles is pathological [e.g. the conduction band of the insulator is near or below the Fermi level, as schematically represented in Fig. 3.1(g)], even in an unpolarized centrosymmetric structure. Furthermore, many perovskites are ferroelectric, and this introduces additional complications that directly affect the band alignment at the electrode interface. One of the most delicate issues is that the band offset generally has a strong dependence on the macroscopic electric displacement field (i.e. on the polarization of the insulator) [52]. As soon as the system becomes polarized (spontaneously in a ferroelectric or under the application of an external field), the imperfect screening at the electrode interface (which can be quantified, as dicussed in Sec. 1.3.2, by means of an interfacial capacitance [50] or, equivalently, by an effective screening length [21]) produces a potential drop [50] that is roughly linear with the magnitude of the polarization [53], and modifies the lineup between the bands of the insulator and the Fermi level of the metal. This phenomenon is central to the physics of ferroelectric capacitors, and has important implications for the stability of a monodomain polar state [21], and for devices based on the tunneling electroresistance effect [104]. In a well-behaved system, the offsets between the metal Fermi level and the band edges of the insulator in close proximity of the interface stay positive upon condensation of the ferroelectric instability [Fig. 3.1(b)], even for a macroscopically thick capacitor where the depolarizing field is negligible and the polarization attains the bulk spontaneous value [Fig. 3.1(c)]. However, a large polarization, combined with a relatively small interface capacitance, can lead to changes in the Schottky barriers that are as large as few electron volts and therefore, to negative values of φn or φp [Fig. 3.1(e-f)] even if they are both positive in the centrosymmetric reference structure [Fig. 3.1(d)]. Throughout this Chapter we revise usual methods for the computation of Schottky barriers in order to test their validity and limits in the case of ferroelectric nanocapacitors. We shall make clear distinction between two qualitatively regimes, corresponding 3.2. General theory of the band offset 51 to (i) that of a normal Schottky alignment and (ii) that of a pathological Ohmic junction. We demonstrate the artifacts typically associated with (ii) by performing extensive calculations of technologically relevant ferroelectric/metal interfaces. We suggest clear criteria to avoid ambiguities in the determination of Schottky barriers and provide recipes for the analysis of results suspicious of being pathological. We discuss the relevant literature works, pointing the attention to those where our results suggest a revision of the currently accepted interpretation. Finally, we discuss a number of viable methodological perspectives to overcome the limitations of DFT illustrated in this work. The research appearing in this Chapter, that has also been published in Ref. [105], was carried out in collaboration with Massimiliano Stengel and Nicola Spaldin. Although for many of the discussions that follow it is difficult to disentangle our original contribution to the work, some parts are clearly due to M. Stengel. We keep those contributions here for the sake of completeness and clarity. However, we will try to mark them clearly all along the Chapter. 3.2 General theory of the band offset The theory of Schottky barriers in metal/semiconductor interfaces is today well established after the huge amount of works devoted to these systems over the last half century. However, the physics governing the band alignment in ferroelectric capacitors significantly departs from the well-established concepts of semiconductor physics. Recently, a theory that intends to account for the particularities that arise when the dielectric material is substituted with a ferroelectric was developed by M. Stengel [105]. Details of this theory will be essential for the analysis of the results reported in Sec. 3.4 and 3.5 so we will make a thorough review of its fundamental points. 3.2.1 Schottky barriers at metal/insulator interfaces The Schottky barrier, a rectifying barrier for electrical conduction across a metal/insulator junction, is of vital importance for the operation of any modern electronic device. For the case of an n-type semiconductor, the Schottky barrier height is the energy difference between the conduction band minimum (EC ) and the Fermi level (EF ) across the interface, and we indicate it as φn . The nature of the microscopic mechanisms governing the magnitude of φn has troubled scientists for several decades. In spite of the ongoing debates, it seems to be widely accepted now that, while bulk materials properties play certainly a substantial role, φn is best understood as a genuine interface property (further discussions on this point can be found in Chapter 4). As a consequence Schottky barriers can not be obtained from a mere comparison the bulk band structure of the two constituting materials, but the explicit role of the interface must be taken into account. The charge rearrangement due to chemical bonding at the interface produces an interface dipole, which translates into a step in the electrostatic potential that acts as the origin of energies shifting the eigenvalues of the materials and uniquely determines the band alignment at the interface 52 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors φn EF metal <VH φp EC EV > ∆<V> dielectric <VH > Figure 3.2: Schematic representation of the band offset at a metal/insulator junction, illustrating the main quantities discussed in the text. (see Fig. 3.2). The interface dipole is, of course, a function of the constituent materials and the termination and orientation of the interface. For this reason the simulation of the actual interface is required for the characterization of Schottky barriers in a given system. The electrostatic Hartree potential at the interface between two semi-infinite solids, Z VH (r) = ρ(r 0 ) 3 0 d r, |r − r 0 | (3.1) where ρ(r) is the total charge density (including electrons and nuclei), is a rapidly varying function of the position, reflecting the underlying atomic structure. In order to filter out the large oscillations and preserve only those features that are relevant on a macroscopic scale, it is convenient to apply an averaging procedure [106, 107]. This consists in (i) performing a global average of VH (r) over planes parallel to the interface, and (ii) convoluting the resulting one-dimensional function with a Fourier filter to suppress the high spatial frequency components. (See Ref. [108] for a detailed description of the method, and Ref. [109] for an extensive review of its applications to Schottky barriers calculations.) After this “nanosmoothing” [108] procedure, and in the absence of a depolarizing field, the doubly-averaged V H (z) reduces to a step function, from which we can extract the electrostatic lineup term [106, 107], ∆hV i = hVHdielectric i − hVHmetal i, (3.2) which includes all the physics of the interface dipole formation. [hVHdielectric i and hVHmetal i are the asymptotic values of V H (z) far from the interface.] To determine the band offsets from ∆hV i it is then necessary to know how the bulk energy bands of the insulator and 53 3.2. General theory of the band offset the Fermi level of the metal are related to their respective average electrostatic potential. In full generality, one can write φp = −EV + EF − ∆hV i, φn = EC − EF + ∆hV i. (3.3a) (3.3b) EV , EC and EF are usually referred to as the band structure term [106, 107], and are bulk properties of the two materials. They are defined as the energy positions of the valence (EV ) and conduction (EC ) band edges of the insulator, and the Fermi level of the metal (EF ), all referred to the average hVH i in the respective bulk (see Fig. 3.2). In Sec. 3.3 we provide further details of the standard computational procedures used to calculate these quantities in practice. In the remainder of Sec. 3.2 we discuss how the above theory needs to be revised and extended in the case of metal/ferroelectric interfaces. This discussion is mostly due to M. Stengel, to whom we acknowledge the permission to reproduce it here. 3.2.2 Theory of Schottky barriers in ferroelectric capacitors Ferroelectric materials entail a new degree of freedom, the macroscopic polarization P , which is absent in the semiconductor case. It is natural then to expect that the above picture of the band offset at metal/insulator interfaces may need to be extended to take this new variable into account. In the following, we discuss how P affects both the lineup and the band-structure terms in Eqs. (3.3a) and (3.3b). Lineup term We represent a simple ferroelectric material as a non-linear dielectric. We have seen in Sec. 1.3.2 that in bulk, a ferroelectric is characterized by an internal energy Ub per unit cell of the form Ub (D) = A0 + A2 D2 + A4 D4 + O(D6 ), (3.4) where D is the electric displacement field, A0 is an arbitrary reference energy, A2 is negative and the higher expansion coefficients are positive. (As we are concerned with the essentially one-dimensional case of a parallel-plate capacitor, we can replace all the vector interfacial quantities of interest by one component only, that corresponds to the direction along which the interface is oriented.) The A0,2,4,... coefficients implicitly contain all the complexity of the microscopic physics, and can be calculated from first principles using the methods of Ref. [51]. It follows from elementary electrostatics [51] that the internal electric field, E(D), is the derivative of U (D), E(D) = where Ω is the cell volume. 1 dU (D) , Ω dD (3.5) 54 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors P D ε 0 λ eff −V(z) M FE λ eff M t λ eff Figure 3.3: Schematic representation of a symmetric short-circuited ferroelectric capacitor in a polarized configuration within the imperfect-screening model. t is the thickness of the ferroelectric film. M and FE represent, respectively, the metal electrode and the ferroelectric film. Both materials are assumed to be separated by a vacuum layer of thickness λeff . Full line represent the electrostatic energy felt by the electrons, i.e. the electrostatic potential times the electron charge. The electrostatics of a parallel-plate capacitor configuration, sketched in Fig. 3.3, was discussed in Sec. 1.3.2, where it was shown that within the “finite screening length” model, the N -layer thick ferroelectric film can be thought as separated from the ideal metal electrode by a thin layer of vacuum, of thickness λeff [50, 47, 53]. As a consequence of the imperfect screening, electric fields develop inside the ferroelectric and the interfacial regions. In Sec. 1.3.2 we found that within this model, the energy of the N -layer thick ferroelectric film can be written as UN (D) = N Ub (D) + 2Sλeff D2 , 2ε0 (3.6) where D is the electric diplacement field, that must be preserved at the interface between the ferroelectric and the vacuum layer, and S is the surface cell area. [Note that two symmetric electrodes of equal λeff are considered in Eq. (3.6).] The second important consequence of a non-zero λeff is that the lineup term, Eq. (3.2), now linearly depends on the external parameter D, due to the additional potential drop at the interface, that can be computed as the product of the electric field within the vacuum layer times its width, ∆hV i(D) = ∆hV i(0) + λeff D . ε0 (3.7) [It is worth noting that, whenever Eb (D) 6= 0, the linear variation of V H (z) introduces an arbitrariness in the determination of ∆hV i(D). Techniques to deal with these issues in practical calculations are described in Ref. [52].] 55 3.2. General theory of the band offset EC 2λeff DS /ε0 EF 11111111111111111 00000000000000000 00000000000000000 11111111111111111 EV 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 00000000000000000 11111111111111111 Polarization reversal 111111111111111111 000000000000000000 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 EC 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 EV 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 000000000000000000 111111111111111111 ∆ <V>(−DS) −V(z) 2λeff DS /ε0 ∆ <V>(D S) −DS DS Figure 3.4: Schematic representation of the band alignment change induced by polarization reversal in a ferroelectric capacitor. Here we assume a ferroelectric layer of infinite thickness (t → ∞), so the depolarizing field vanishes and therefore the polarization attains for the bulk spontaneous value, PS . Since the field is zero, D = PS . Also, because of the vanishing field in the ferroelectric we can represent the macroscopic potential as flat. In the scheme we assume that the band-alignment is not pathological when the polarization points to the left. But, upon polarization reversal, that change in the potential lineup is larger than the fundamental band-gap and the system becomes pathological. Table 3.1: Estimation of the change in the lineup term ∆φ of typical ferroelectric capacitors upon polarization reversal. DS is the bulk spontaneous polarization of the ferroelectric material. λeff were calculated in Ref. [47] for capacitors with SrRuO3 electrodes. BaTiO3 PbTiO3 DS (C/m2 ) 0.39 0.75 λeff (Å) 0.20 0.15 ∆φ (V) 1.8 2.6 56 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors Non polar PbTiO3 Polar PbTiO3 5 4 3 Energy (eV) 2 1 Eg = 1.45 eV Eg = 1.35 eV 0 -1 -2 -3 -4 -5 Γ Z R A Γ X Γ Z R A Γ X Figure 3.5: Band structure of centrosymmetric and polar tetragonal bulk PbTiO3 obtained within the Siesta code and the computational parameters described in Sec. 3.3.4. In-plane lattice constant is constrained to the theoretical one of SrTiO3 (3.874 Å). The polar structure is fully relaxed both the atomic coordinates and out-of-plane cell vector. To give a more quantitative flavor of the impact of this D-dependence in real systems, we can use the values of λeff reported in the literature for PbTiO3 /SrRuO3 and BaTiO3 /SrRuO3 capacitors. As is represented squematically in Fig. 3.4, upon polarization reversal, the interface lineup term ∆hV i will undergo a variation corresponding to DS ∆φ = ∆hV i(DS ) − ∆hV i(−DS ) = 2λeff , (3.8) ε0 where DS is the spontaneous polarization of the ferroelectric material (in the spontaneous configuration the internal electric field within the ferroelectric vanishes and DS equals the spontaneous polarization). The values reported in Table 3.1 indicate that this effect can be rather large, of the order of 2 – 3 eV. Those values are larger than the fundamental LDA band gaps of BaTiO3 and PbTiO3 (1.58 eV and 1.35 eV respectively). Therefore, even if the band alignment is non-pathological in the paraelectric configuration, in both cases it will indeed become pathological once the ferroelectric instability is fully relaxed. Band-structure term The polar displacements in the ferroelectric film modify not only the lineup term, but also the bulk band-structure term. This is most easily understood by recalling the role played by covalent bonding in the ferroelectric instability of perovskite titanates. This implies that the polar distortions significantly modify both the conduction and valence band structure. For example, in both BaTiO3 and PbTiO3 the fundamental gap typically increases when going from the centrosymmetric structure to the polar tetragonal phase (see Fig. 3.5 for the case of PbTiO3 ). Using the arguments of Ref. [52], we can think of a continuous dependence of both EV and EC , respectively in Eq. (3.3a) and Eq. (3.3b), 3.2. General theory of the band offset 57 on the electric displacement D. The Fermi level EF , of course, remains fixed as the electric displacement does not affect the bulk of the metallic electrode. In summary, the general expression for the n-type Schottky barrier at a metal/ferroelectric interface (an analogous expression follows for the p-type one) is φn (D) = EC (D) − EF + ∆hV i(D), (3.9) where at the lowest order EC is quadratic in D (the linear order is forbidden by symmetry), and in most cases of interest ∆hV i(D) can be approximated by a linear function as in Eq. (3.7). In the following, we shall elaborate on this expression and identify a new, qualitatively different regime, with important implications for the physics of the interface. 3.2.3 Ferroelectric capacitors in a pathological regime Equation (3.9) implies that φn (D) might become negative for some values of D. From the point of view of first-principles calculations, already by looking at the values of Table 3.1 we can be reasonably sure that this will happen at the PbTiO3 /SrRuO3 interface: 2.6 eV is already larger than the LDA gap of PbTiO3 in the ferroelectric phase (∼1.45 eV). This possibility has been almost systematically overlooked in the literature. As this is a central point of this work, we shall illustrate in detail the consequences of such a regime, and explain why we regard it as “pathological”. We discuss in the following two possible occurrences of this scenario: (i) φn is negative already in the paraelectric configuration at D = 0 and (ii) φn is positive at D = 0 but becomes negative at some value of |D| < DS . The centrosymmetric case We start with a capacitor in the reference paraelectric structure with two symmetric electrodes, and we hypothesize that, for whatever physical reason, the interface dipole that forms between the metal and the film leads to a negative φn . (Similar arguments apply to the case, not explicitly discussed here, of a negative φp .) As the quantum states of the conduction band of the film lie at lower energy than the Fermi level of the metal, the former will be filled up to EF , leading to a nonzero free charge density, ρfree , in the film. Neglecting quantum confinement effects, sufficiently far from the interfaces we can approximate the density of states of the insulating material in the capacitor with its bulk density of states ρb (E). Within this approximation, ρfree is exactly given in terms of φn , Z e EC −eφn ρfree = − ρb (E)dE. (3.10) Ω EC Notice that in the pathological regime, φn < 0 and EC − eφn > EC . This additional charge density, superimposed to an otherwise charge-neutral insulating film, will produce a strong electrostatic perturbation in the system. For example, if such a charge rearrangement occurred in vacuum, the Poisson equation d2 V (z) ρfree =− , dz 2 ε0 (3.11) 58 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors would imply a parabolic potential of the form V (z) = − ρfree 2 z . 2ε0 (3.12) (We assume that z = 0 corresponds to the center of the ferroelectric film.) Throughout this work, we shall assume that the interface is oriented along the z axis, and each material is periodic in the plane parallel to the interface, referred to as the (x, y) plane. As typical ferroelectric materials are exceptionally good dielectrics, in a first approximation we can assume that V (z) will be perfectly screened by the polar displacements of the lattice. However, this does not mean that electrostatics has no consequences – quite the contrary. Macroscopic Maxwell equations in materials indeed dictate that dD(z) = ρfree . dz (3.13) Hence, if we assume perfect bulk screening, we have E(z) = 0, D(z) = ε0 E(z) + P (z) = P (z) and, after integrating Eq. (3.13), P (z) = ρfree z. So, since the sign of the electronic charge and ρfree is negative within our convention, we have a non-uniform and linearly decreasing polarization in the ferroelectric film [see Fig. 3.6(d)]. This means that, at the film boundaries (z = ±t/2, where t is the thickness), the local electric displacement has now opposite values, proportional to the total amount of free charge that was transferred, t t D(− ) = − ρfree , 2 2 t t D( ) = ρfree . 2 2 (3.14) Of course, the band offset at the interface depends on the local value of D in the film region adjacent to the interface, so φn will be consequently shifted in energy according to Eq. (3.9). We can expect that for small D values the (quadratic) polarization effects on the band structure will be less important than the (linear) dependence of the lineup term on D. (Note that the presence of additional charge in the conduction band might also alter the bandstructure term, e.g. through on-site Coulomb repulsions or other exchange and correlation effects; in the limit of weak correlations we expect these to be even smaller and essentially irrelevant for this discussion.) Therefore, we approximate Eq. (3.9) with Eq. (3.7), and write φn = φ0n + λeff D tλeff ρfree = φ0n − . ε0 2ε0 (3.15) [The minus sign comes from the fact that at the z < 0 interface, which is the one for which Eq. (3.7) is valid within our conventions, D is positive.] In turn, the new φn will modify ρfree through Eq. (3.10). For some value of φn , Eq. (3.10) and Eq. (3.15) will be mutually self-consistent and the system will reach electrostatic equilibrium. This can be expressed through an integral equation where we have eliminated ρfree , Z e EC −eφn 2ε0 (φn − φ0n ) ρb (E)dE = . (3.16) Ω EC tλeff 59 3.2. General theory of the band offset (a) (b) EF φ 0n EF φn CBM (c) (d) D −t/2 0 D t/2 z z Figure 3.6: Schematic representation of the effect of free-charge redistribution onto the band diagram of a paraelectric capacitor with a negative φn . (a) band alignment under perfect interface screening (i. e. when ρfree vanishes), and (b) after charge spill-out and electrostatic reequilibration. The corresponding profile of the electric displacement field within the ferroelectric films are displayed in panels (c) and (d), obtained after integrating Eq. (3.13). To qualitatively appreciate the physical implications of this expression, we can explicitly solve it by using a constant ρb (E) = α. (Note that this assumption is not completely unrealistic as the t2g bands forming the bottom of the conduction band in many ferroelectric perovskites have a marked two-dimensional character – recall that the density of states of a free electron band in two dimensions is a step function.) This leads to φn − φ0n e2 tλeff α , =− φn 2ε0 Ω (3.17) and with a few rearrangements to φn = φ0n , Ctλeff α̃ + 1 (3.18) where C = e2 /2ε0 is a constant, and α̃ = α/Ω is the density of states per unit energy and volume of the bulk. In spite of the drastic simplifications, Eq. (3.18) already contains most of the relevant ingredients for our analysis. A few notable ones are missing – we shall come back to those below. Before going into more detailed considerations, however, it is important to spell out the direct implications of Eq. (3.18), which we shall be concerned with in the following. 60 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors First, note that all quantities appearing at the denominator at the right-hand side of Eq. (3.18) are positive. Since we are assuming a pathological regime (φ0n < 0), this means that φn will be negative, and will satisfy φ0n < φn < 0. The lower limit corresponds to the perfect interface screening case: λeff = 0 and changes in D in the ferroelectric are perfectly screened in the interface. The upper limit corresponds to no screening: λeff → ∞ and bound charges at the interface due to changes in D directly affects the interfacial dipole that determine the band-offset. The situation is schematically represented in Fig. 3.6(a) and Fig. 3.6(b). Given a negative φ0n [Fig. 3.6(a)], the charge redistribution will induce an upward energy shift of the conduction band minimum, bringing φn closer to the Fermi level [Fig. 3.6(b)]. Second, in the limit of t → ∞ (infinite thickness) φn will tend to zero from below as φn ∝ −1/t. This means that the self-consistent band offset φn is not determined by the local physical properties of the junction, i.e. it is no longer an interface property – the spilled-out charge will redistribute over the whole film thickness as t is varied. Third, the density of states of the conduction band, represented in Eq. (3.18) by the parameter α, will also affect the value of φn : the larger α, the strongest the reduction in φn upon charge spill-out and electrostatic reequilibration. (To avoid confusion, note that in the above paragraphs, we used the word “screening” in two different contexts. By “perfect bulk screening” we mean Eb (D) = 0. By “perfect interface screening” we mean λeff = 0.) We can attempt a semiquantitative assessment of Eq. (3.18) in a representative capacitor of thickness t = 50 Å (comparable to those that are typically simulated within DFT). In atomic units, we use λeff = 0.3 (of the order of the values reported in Table 3.1), C = 2π, and α̃ = 0.05 (appropriate for the conduction band of SrTiO3 , a prototypical perovskite material). We obtain φ0 φn ∼ n . (3.19) 10 This implies that the effect is quite strong – even if φ0n is a rather large negative value (e.g. of the order of -1 eV), in most practical cases the conduction charge redistribution will reduce it to a value that lies just below the Fermi level. Most importantly, this implies that, when φ0n < 0, the physical parameters, φ0n and λeff , governing the band offset at the interface are neither accessible in a simulation, nor are they directly measurable in an experiment – only φn might be. Note, however, that the “self-consistent” φn value is generally not a well-defined physical quantity – this is only true within the many approximations used in the above derivations. In particular, we have neglected bandbending effects: in general the electrostatic potential will be non-uniform in the film (see rubric Towards a quantum model below) and φn will be a function of the distance from the interface. But even if we put this caveat aside for a moment, the reader should keep in mind that φn is determined here by space-charge effects through several independent contributions. Furthermore, the film is no longer insulating but becomes a metal. This is a substantial, qualitative departure from the physical concepts that were developed in the context of semiconductor/metal interfaces, and that led to the consensus understanding of φn as a genuine interface property. Given this situation, one needs to revisit the very foundations of the methodological 61 3.2. General theory of the band offset (a) (b) P CBM EF EF M FE M M FE M Figure 3.7: (a) Paraelectric capacitor with a Schottky-like band alignment in the paraelectric structure. (b) When the polar instability sets in, the band alignment becomes pathological, the conduction band is locally populated (red shaded area) and the film becomes partially metallic (light shaded area bounded by the dashed line). ab-initio approaches that have been used with great success in the past to compute Schottky barriers heights. This success has critically relied on a key observation: the interface dipole, that one identifies with the lineup term Eq. (3.2) is a ground-state property, i.e. is not directly affected by the well-known limitations of the Kohn-Sham eigenvalue spectrum. This would be excellent news: one could efficiently (and accurately) calculate ∆hV i within DFT, and combine it with a band-structure term (EV or EC ) calculated at a higher level of theory (e.g. GW); within this formally sound procedure, theoretical calculations have shown remarkable agreement with the experimental observations in the past. In the spill-out regime (i.e. φ0n < 0) described in this Section the above key observation no longer holds – the erroneous DFT value of φ0n plays a direct and dominant role in the interface dipole formation, as it is apparent from Eq. (3.18). Furthermore, as φ0n is systematically underestimated within LDA or GGA, there is the concrete possibility that the spill-out regime itself (φ0n < 0) might be an artifact of the band-gap problem. Thus, the ground-state properties of the system found in a simulation might be qualitatively wrong due to this issue, in loose analogy to, e.g., the erroneous LDA prediction of metallicity in many transition metal compounds. It goes without saying that the results of a simulation where significant spill-out of charge is found because of the mechanism described in this Section should be regarded with great suspicion. The broken-symmetry case Even if the band alignment is Schottky-like in the reference paraelectric structure of the capacitor, Eq. (3.9) entails the possibility that it might become pathological in the ferroelectric regime (i.e. when a polar instability is allowed to fully relax). Unfortunately, for this case many of the simplifying assumptions used above are no longer valid, and for a detailed description one would need to take into account the more refined physical ingredients discussed in the next rubric. At the qualitative level, however, we can already draw some important conclusions, as we shall briefly illustrate in the following. Equation (3.9) predicts that, if φ0n is positive and the capacitor is compositionally symmetric [as in Fig. 3.7(a)], at finite D at most one of the two opposite interfaces 62 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors will have a negative φn . This implies that only part of the ferroelectric film, i.e. the region adjacent to this “pathological” interface, will become metallic, while the rest of the film will stay insulating [Fig. 3.7(b)]. (To understand this point, note that at difference with the previous case one has now a finite “depolarizing” electric field in the insulating part of the capacitor. This wedge-like potential will keep the conduction electrons electrostatically confined to the pathological side.) In the insulating region, the polarization will be macroscopically constant, as in a well-behaved capacitor [recall Eq. (3.13)]. According to the same Eq. (3.13), D(z) [and hence P (z)] will be nonhomogeneous, with a negative slope, in the metallic region. In this context it is worth pointing out an important physical consequence of such a peculiar electronic ground state. This concerns the response of the capacitor to an applied bias potential. In wellbehaved cases, the polarization of the capacitor will respond uniformly to a bias, i.e. all the perovskite cells up to the electrode interface will undergo roughly the same polar distortion. In the present “ferroelectric-pathological” regime, part of the ferroelectric film has become metallic, i.e. the metal/insulator interface has moved to a place that lies somewhere in the film. This means that, if one tries to switch the device with a potential, the electric field won’t affect the dipoles that lie closest to the pathological interface – they will be screened by the spilled-out free charge. A consequence is that the dipoles near a pathological interface will appear as if they were pinned to a fixed distortion, that is almost unsensitive to the electrical boundary conditions. This pinning phenomenon has been studied in earlier theoretical works, and was ascribed to chemical bonding effects. In Sec. 3.5 we shall substantiate with practical examples that “dipole pinning” is instead a direct consequence of the problematic band-alignment regime described here. In Sec. 3.6 we shall come back to this point and put it in the context of the relevant literature. Towards a quantum model In order to draw a closer connection between the semiclassical arguments of the previous sections and the quantum-mechanical results that we present in Sec. 3.4 and 3.5, we briefly discuss here how to improve our physical understanding of the charge spill-out process by lifting some of the simplifying approximations used so far. As a detailed treatment goes beyond the scopes of the present work, we shall limit ourselves to qualitative considerations. The most drastic approximation of our model appears to be the assumption of perfect dielectric screening within the ferroelectric material, where the spill-out charge is perfectly compensated by the polar displacements of the lattice. This implies that the electric field in the film vanishes, and the excess conduction charge can spread itself spatially at essentially no cost. In this scenario, the macroscopically uniform distribution of ρfree postulated in Sec. 3.2.3 appears very reasonable. In reality, the internal E field in the bulk ferroelectric material does not vanish, but is a non-linear function of D, that can be written by combining Eq. (3.4) and Eq. (3.5), Eb (D) ∼ 1 2A2 D + 4A4 D3 . Ω (3.20) 63 3.2. General theory of the band offset (a) (b) CBM EF M CBM EF FE M M Dielectric M Figure 3.8: Schematic representation of the effects of dielectric nonlinearity onto the band diagram of a centrosymmetric capacitor. The effective potential felt by the conduction electrons is −V H (z). (a): Ferroelectric material (in a non-polar configuration). (b): Dielectric material. Of course, solving for the self-consistent ρfree (z) in a non-linear medium would require a numerical treatment. Still, we can gain some insight about qualitative trends by starting, for example, from the linearly decreasing P (z) found in the centrosymmetric case. Even though we are treating now a non vanishing electric field, the large dielectric constant of ferroelectric materials makes reasonable to approximate D(z) ∼ P (z) = ρfree z. Using Eq. (3.20) we can write E(z) = 1 2A2 ρfree z + 4A4 ρ3free z 3 . Ω (3.21) Since E(z) = − dV H (z) , dz (3.22) The electrostatic potential is then given by integrating E(z) from the interface to a position z within the ferroelectric V H (z) = − Z 0 z E(z 0 )dz 0 = − A2 ρfree z 2 A4 ρ3free z 4 − . Ω Ω (3.23) [Here we are assuming the interface to be located at z = 0, using the previous reference position of the interface at −t/2 only adds a constant to Eq. (3.23) and does not affect this discussion.] Using again D(z) ∼ ρfree z, we get V H (z) ∼ − A2 D2 (z) A4 D4 (z) − , Ωρfree Ωρfree (3.24) which, comparing with Eq. (3.4), essentially leads to V H (z) = Ub [D(z)]/Q0 , (3.25) 64 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors where Ub is the internal electrostatic energy of the bulk ferroelectric, and Q0 = −Ωρfree is a (positive) constant of the dimension of a charge. This means that the spatial variation in V H (z) reflects the energy landscape of the bulk material: V H (z) will be a double-well potential in a ferroelectric material (A2 < 0), and a single-well potential in a dielectric material (A2 > 0). Remarkably, the double-well potential accounts for the possibility of free-charge accumulation in the middle of the centrosymmetric film [Fig. 3.8(a), notice that the band deformation is given by −eV H (z), and thus it displays the shape of an inverted double well]. This excess of negative charge in the middle of capacitor would help to stabilize even further the head-to-head domain wall in the polarization P (z). Conversely, for a paraelectric material one would expect the free charge to be loosely bound to the interface, and have a minimum in the middle of the film [Fig. 3.8(b)]. Of course, these considerations are valid for a centrosymmetric capacitor, and are presented just to give the reader an idea of the complications involved in the analysis of this phenomenon. A second important approximation is the neglect of (i) quantum confinement effects beyond the simple Thomas-Fermi filling of the bulk-like density of states and (ii) the band-structure changes due to the polar distortions, which we briefly mentioned in Sec. 3.2.2. These will further modify the equilibrium distribution of the free charge, and we expect them to be important to gain a truly microscopic understanding of the system, although not essential for the main scopes of this work. Remarkably, a promising model taking all these ingredients into account (dielectric non-linearity and bandstructure effects) was recently proposed in the context of the (at first sight unrelated) LaAlO3 /SrTiO3 interface. [110] This indicates that the physics of a ferroelectric capacitor in the pathological band-alignment regime described here is essentially analogous to that of the “electronic reconstruction” [111] in oxide superlattices. 3.2.4 Implications for the analysis of the ab-initio results The above derivations show that there are two qualitatively dissimilar regimes in the physics of a metal/insulator interface, Ohmic-like and Schottky-like. During the derivation, we have evidenced some distinct physical features that we expect to be intimately associated to the “pathological” Ohmic case. As these are of central importance to help distinguish one scenario from the other, we shall briefly summarize them in the following, mentioning also how each of these “alarm flags” can be detected in a first-principles simulation. First, even after the electron reequilibration takes place, the band edges cross the Fermi level of the metal, i.e. the apparent Schottky barrier is negative. Therefore, the analysis of the local electronic structure and of the Schottky barriers appears to be the primary tool to identify a pathological case. However, as the “self-consistent” φn tends to stay very close to the Fermi level, this analysis should be performed with unusual accuracy – techniques to do this will be discussed in Sec. 3.3.1. Second, the presence of a substantial density of free charge populating the conduction band of the insulator is another important consequence of the pathological regime. In 65 3.3. Methods Sec. 3.3.2 we illustrate how to rigorously define ρfree in a ferroelectric heterostructure. Finally, a remarkable consequence of charge spill out is the presence of an inhomogeneous polarization in the system. Note that this feature has been ascribed in earlier works to phenomena of completely different physical origin. We shall devote special attention in Sections 3.4 and 3.5 to demonstrating the intimate relationship between ρfree and spatial variations in P . 3.3 Methods In this Section we spell out the practical techniques that we use to extract the Schottky barriers’ height from first-principles calculations, the operational definitions of free charge and bound charge, and the methods we use to control the electrical boundary conditions in supercell calculations. We also summarize the other relevant computational parameters used in Sec. 3.4 and 3.5. 3.3.1 Schottky barriers from ab initio simulations First, we briefly review the methods that were used in earlier works to compute Schottky barriers at metal/semiconductor interfaces, pointing out advantages and limitations of each of them. Then, we illustrate potential complications that might arise, with special focus on ferroelectric oxide systems and the issues discussed in Sec. 3.2. From the local density of states In order to calculate the band offset at a metal/insulator interface, one needs to identify the location of the band edges deep in the insulating region, with the Fermi level of the metal taken as a reference. To that end, it has become common practice[112] to define a spatially-resolved density of states, XZ ρ(i, E) = dk |hi|ψnk i|2 δ(E − Enk ), (3.26) n BZ where |ii is a normalized function, localized in space around the region of interest. When |ii = |ri is an eigenstate of the position operator, the resulting ρ(r, E) is commonly known as local density of states (LDOS). Conversely, when |ii = |φnlm i is an atomic orbital of specified quantum numbers (n, l, m), we call it instead projected density of states (PDOS). The integral is performed over the first Brillouin zone (BZ) of the supercell and the sum runs over all the bands n. Enk stands for the eigenvalue of the one-particle wave function ψnk . The LDOS defined in Eq. (3.26), that depends on the position in real space as well as in the energy, gives a very intuitive picture of the band offset: “sufficiently far” away from the interface, the LDOS converges to the bulk one of the corresponding crystal [112], and in principle the location of the band edges (and hence the Schottky barriers) can be easily extracted following the next steps: (i) we integrate Eq. (3.26) over the 66 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors central unit cell of the dielectric (again assuming that we are sufficiently far away from the interface so that the LDOS is bulk-like) and (ii) we compare the position of the Fermi level of the whole heterostructure with the band edges obtained from the previous integration. However, several approximations are used in practice to make the calculation tractable, and these can introduce significant deviations in the Schottky barriers computed by means of either the LDOS or PDOS. First, all studies are done on a finite supercell, usually with a symmetric capacitor geometry. This implies that the LDOS of the most dispersive bands will be altered by quantum confinement effects, which might produce a spurious gap opening. Also, the LDOS associated to the evanescent metal-induced gap states (MIGS) might be still important at the center of an insulating film that is not thick enough, thus preventing an accurate identification of the band edge. Second, as we explained in Sec. 2.7, a discrete k-point mesh is used instead of the continuous one implicitly assumed in Eq. (3.26). Such a k-point mesh is generally optimized for efficiency, which means that high-symmetry points are often excluded 1 . As the edges of the valence and conduction band manifolds are usually located at the high symmetry points 2 , extracting those features from the calculated LDOS might lead to substantial inaccuracies. For materials that display a very dispersive band structure (see e.g. Ref. [114]) it is not unusual to have deviations of the order of several tenths of an eV. Third, a fictitious electronic temperature (or Fermi surface smearing) is commonly used, in order to alleviate the errors introduced by the k-mesh discretization. This implies that the Dirac delta function in Eq. (3.26) is actually replaced by a normalized smearing function with finite width. This is a again potential source of inaccuracies, because the apparent edges of the smeared LDOS/PDOS actually might not correspond to the physical band edges but to the (artificial) tail of the smearing function used. Summarizing the above, we get to the following operational definition of the smeared LDOS, X ρ̃(r, E) = wk |ψnk (r)|2 g(E − Enk ), (3.27) nk where the BZ integral has been replaced with a sum over a discrete set of special points k with corresponding weights wk , and the Dirac delta has been replaced with a smearing function g. As it will become clear shortly, it is very important to use in Eq. (3.27) a g function that is minus the analytical derivative of the occupation function f (E) defined in Sec. 2.7, and used in the actual calculations to determine the population of the one-particle eigenfunctions during the selfconsistency procedure. Only in that case the position of the Fermi level with respect to the LDOS obtained from the integration 1 In practical simulations, the origin of the k-point grid may be displaced from k = 0 in order to decrease the number of inequivalent k-points [90, 113]. This shift usually prevents the appearance of high-symmetry points from the list of k-points used during the self-consistent procedure or in the calculations of the density of states. 2 The band gap of both BaTiO3 and PbTiO3 is indirect, with the top of the valence band located at R in BaTiO3 and at X in PbTiO3 , and the bottom of the conduction band at Γ in both materials. 67 3.3. Methods of Eq. (3.27) is consistent with the actual population of the conduction or valence bands in the calculation (a detailed analysis is provided in Appendix A). Consequently the corresponding Gaussian (G) and the Fermi-Dirac (FD) smearing functions are E − EF σ 1 fFD (E) = (E−E )/σ F e +1 1 fG (E) = erfc 2 ⇒ ⇒ 1 2 2 gG (E) = √ e−(E−EF ) /σ , πσ σ −1 gFD (E) = , 2 + e(E−EF )/σ + e−(E−EF )/σ (3.28a) (3.28b) where σ is the smearing energy (or electronic temperature in the case of the Fermi-Dirac distribution, with σ = kB T ) used during self-consistent minimization of the electronic ground state. From the electrostatic potential To work around these difficulties, it is in most cases preferable to avoid the direct estimation of the Schottky barriers based on the LDOS/PDOS, and use instead the indirect procedure, based on the nanosmoothed electrostatic potential, V H , described in Sec. 3.2.1. The lineup term ∆hV i – that can only be obtained from the simulation of the actual interface, and thus represents the computationally most expensive part of the Schottky barrier calculation – generally converges much faster than the LDOS/PDOS with respect to all the computational parameters described above (slab thickness, kmesh, Fermi surface smearing). (A notable exception is the pathological spill-out regime described in Sec. 3.2 – for further details see below.) The band-structure terms, EV and EC , can be then accurately and economically evaluated in the bulk, without the complications inherent to MIGS and quantum confinement effects. Finally, as depicted schematically in Fig. 3.2, the band structure terms are shifted according to the spatially varying energy reference given by the lineup term ∆hV i to obtain the values of the Schottky barriers of the interface. While this is in principle a very convenient and robust methodological framework it is, however, also prone to systematic errors. In particular, great care must be used when performing the reference bulk calculations. In the vast majority of cases these must not be performed on the equilibrium structure of the bulk solid, but will be constructed to accurately match (i) the mechanical and (ii) the electrical boundary conditions of the insulating film in the supercell. The issue (i) is well known: in a coherent heterostructure the insulating film is strained to match the substrate lattice parameter, and for consistency the “bulk” calculation should be performed at the same in-plane strain. (The dependence of the band-structure term on the lattice strain is well known in the literature, and referred to as “deformation potentials” [115].) Issue (ii) concerns ferroelectric systems, and is therefore not widely appreciated within the semiconductor community. Whenever the symmetry of the capacitor is broken and there is a net macroscopic polarization in the ferroelectric film, the structural distortions may alter the band structure significantly, often more than purely elastic effects do [110]. Note 68 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors that in most capacitor calculations the film is only partially polarized (i.e. it has neither the centrosymmetric non-polar structure, nor the fully polarized ferroelectric structure because of the depolarizing effects described in Sec. 3.2.2). The “bulk” reference calculation should then accurately match the polar distortions of the film, extracted in a region where the interface-related short-range perturbations have healed into a regular pattern. The “best of both worlds” In order to minimize the drawbacks associated with either of the two methods described above, we find it very convenient to combine them in the following procedure. 1. We compute the LDOS in the supercell at an atomic site (or layer) located far away from the interfaces, where the relaxed atomic structure has converged into a regular pattern. 2. We extract the relaxed atomic coordinates from the same region of the supercell, and build a periodic bulk calculation based on them, by preserving identical structural distortions and strains, and by using an equivalent k-mesh. (An approximation is made here, since the periodic bulk simulation is carried out at zero macroscopic field while the LDOS in the supercell might be computed at a nonzero depolarizing field. The problem of computing the bulk layer by layer LDOS under a finite electric field remains an open question.) 3. We extract the LDOS from the bulk for the same atomic site or layer; we construct the bulk LDOS using Eq. (3.27) and an identical g function to that used in the supercell. 4. Finally, we superimpose the bulk LDOS to the supercell LDOS at each layer j; we align them by matching the sharp peaks of a selected deep semicore band, supercell bulk . The deep semicore states are (j) and Esc which are located at energies Esc insensitive to the chemical environment and have negligible band dispersion; this means that they provide an excellent, spatially localized reference energy for the estimation of the lineup term. At this point, we look at either LDOS curve in a vicinity of the Fermi level. If it is non-zero we are probably facing a pathological spill-out case (see the following Section). If it is zero, then we can go one step further and accurately estimate the position of the bulk and E bulk , local band edges. To this end, we compute from the bulk calculation EC V bulk . (A further non-selfconsistent run might be needed if the original ktogether with Esc mesh did not include the high-symmetry k-points where the band edges are located.) In all cases these values should be directly extracted from the actual eigenvalues, and never supercell from the tails of the smeared LDOS. Finally, assuming that Esc (j) are all referred to an energy zero corresponding to the self consistent Fermi level of the supercell, we define the local position of the band edges as 69 3.3. Methods supercell supercell bulk bulk EC,V (j) = Esc (j) + (EC,V − Esc ). (3.29) This procedure avoids the (often inaccurate) estimate of the band edges based on the tails of the smeared LDOS, and at the same times preserves the advantages of the “lineup + supercell band structure” technique (where Esc (j) is playing the role of ∆hV i). In principle, the latter method should accurately match the results of Eq. (3.29), except for quantum confinement effects in the metallic slab used to represent the semi-infinite electrode, as discussed in Ref. [116]. Note that this technique is not only useful to detect pathological band alignments and extract accurate band offsets in the non-pathological cases. Given that we are superimposing two LDOS calculated with identical computational parameters and structures, their direct comparison can be very insightful. Most importantly, one expects all the features to closely match unless there are MIGS or confinement effects. Therefore, one has also a powerful tool to directly assess the impact of the latter physical ingredients in the supercell electronic structure. This procedure, therefore, yields far more physical information than the separate use of either the PDOS/LDOS or the nanosmoothing method. We systematically applied this analysis in our results presented in Sections 3.4 and 3.5. Pathological regime In the pathological regime described in Sec. 3.2, many of the conditions that formally justify application of the above methods to the estimation of the SBH break down. First, the presence of a non-uniform electric displacement D(z) implies that the polar distortions are also non-uniform, and they may not converge to a regular bulk-like pattern anywhere in the film. Second, electrostatic and exchange-correlation effects due to the partial filling of the conduction band imply that the band structure may significantly depart from what one computes in the insulating bulk (note that this has nothing to do with the effect of the structural distortions discussed in the previous Section). Third, the usual assumption of fast convergence of the interface dipole with respect to slab thickness, k-mesh resolution and smearing energy also breaks down, as the conduction band DOS (which converges slowly with respect to these parameters) is now directly involved in the electrostatic reequilibration process. Based on this, the reader should keep in mind that there is an intrinsic arbitrariness, of physical more than methodological nature, in the definition of the band edges in spillout cases. This arbitrariness reflects itself in the fact, already pointed out in Sec. 3.2, that the band alignment at a pathological interface is no longer a well-defined interface property, nor it is directly measurable in an experiment. The position of the bands is essentially the result of a complex electron redistribution process that may occur on a scale that is almost macroscopic, and is driven by different factors than those usually involved in the Schottky barrier formation. 70 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors Of course, by using all the precautions that are valid at well-behaved interfaces one might still gain some qualitative insight into the local electronic properties of the system. However, the data must be interpreted with some caution, and it is most appropriate to combine the analysis with other post-processing tools before drawing any conclusion. We shall discuss some of these further analysis tools in the following Sections. 3.3.2 Electrical analysis of the charge spill-out In this Section we introduce the methodological tools that we use to analyze in practice the spill-out regime, in light of the theory developed in Sec. 3.2. In particular, we illustrate how to rigorously define the “local electric displacement” D(z) and the “conduction charge” ρfree . To evaluate the former, we discuss two approaches. The first one is based on a Wannier decomposition of the bound charges. The second one is an approximate formula in terms of the ionic distortions and the Born effective charges. This simplified formula is very practical for a quick analysis, but is generally affected by systematic errors. This issue is addressed using a simple correction proposed by M. Stengel that significantly improves the accuracy of the estimation based on the Born charges [105]. Definition of bound charge and conduction charge In a typical metal, it is difficult to rigorously identify conduction electrons and bound charges, as usually the respective energy bands intersect each other in at least some regions of the Brillouin zone. (This is true, for example, in all transition metals, where the delocalized sp bands cross the more localized d bands.) By contrast, in all perovskite materials considered here, even upon charge spill out and metallization a well-defined energy gap persists between the bound electrons and the partially filled conduction bands. Therefore, it is straightforward to separate the two types of charge densities, free and bound, simply by integrating the local density of states, defined in Eq. (3.26), over two distinct energy windows. For example, for the conduction charge ρfree we have Z EF X ρ̃(r, E)dE = ρfree (r) = wk fnk |ψnk (r)|2 , (3.30) E0 εnk >E0 where E0 is an energy corresponding to the center of the gap between valence and conduction band, ρ̃ is the smeared density of states of Eq. (3.27), fnk are the occupation numbers and the sum is restricted to the states with eigenvalue Enk higher than E0 . [Note that Eq. (3.30) only holds if the g-smearing of ρ̃ is compatible with the definition of fnk , see more details about this discussion in Sec. 3.3.1 and Appendix A.] Since we are working with layered systems that are perfectly periodic in plane, we will be mostly concerned with the planar average of ρfree , Z 1 ρfree (z) = ρfree (r)dxdy, (3.31) S S where S is the area of the interface unit cell. In some cases, it is also useful to consider the nanosmoothened function, [108] which we indicate by a double bar symbol, ρfree (z). 71 3.3. Methods Of course, we could use a similar strategy to extract ρbound , but in practice we find it more convenient to work with the local polarization P (z), as it is more closely related to the way that ferroelectric materials and superlattices are usually discussed in the literature. Techniques to extract P (z) are described in the following sections. Local polarization via Wannier functions A very useful tool to describe the local polarization properties of layered oxide superlattice are the “layer polarizations” introduced by Wu et al. [117] First, the electronic ground state is transformed into a set of “hermaphrodite” Wannier orbitals [117, 118] by means of the parallel-transport [119] procedure. Note that the parallel-transport procedure is restricted only to the orbitals that we consider as “bound charge”, i.e. those with an energy eigenvalue lower than E0 . Then, the Wannier centers and the ion cores are grouped into individual oxide layers, and the dipole density of layer j is defined as pj = X 1X Zα Rαz − 2e zi , S α∈j (3.32) i∈j where Zα is now the bare valence charge of the atom α, whose position along z is Rαz , and zi is the location of the Wannier orbital i. Note that individual oxide layers in II-IV perovskites like BaTiO3 or PbTiO3 are charge-neutral and pj are well-defined; however, in I-V perovskites like KNbO3 , individual layers are charged, and pj become meaningless as they are origin-dependent. To circumvent this problem, one can either combine the layers two by two as was done in Ref. [71], or perform some averaging with the neighboring layers, as for example in Ref. [118]. It is important to keep in mind that, depending on the specific averaging procedure, one might end up with the formal or with the effective local polarization [120]; in this work we find it more convenient to work with the latter. As we do not need, for the purpose of our discussion, to resolve P into contributions from individual AO and BO2 oxide layers, at variance with Ref. [118] we perform a simple average 1 1 1 p̄j = pj−1 + pj + pj+1 . (3.33) 4 2 4 We then define the local polarization by scaling this surface dipole density by the average out-of-plane lattice parameter, c, of the oxide film, and by taking into account that every individual oxide layer occupies only half the cell. We thus define the local polarization as 2 Pj = p̄j . (3.34) c The local polarization Pj is, of course, a discrete set of values, but we can think of it as a continuous function of the z coordinate, P (z), which is sampled at the oxide plane locations. In the remainder of this work, we will write Pj or P (z) depending on the context, but the reader should bear in mind that these two notations refer to the same object. 72 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors Approximate formula via Born effective charges While the above definition of Pj in terms of Wannier functions is accurate and rigorous, it is not immediately available in most electronic structure codes. An approximate estimate of the local polarization can be simply inferred from the bulk Born effective charges Zα∗ , defined in Sec. 1.2.2, and the local atomic displacements. Analogously to the above formulation, we can write the Zα∗ -based approximate layer dipole density, pZ j , as pZ j = 1X ∗ Zα Rαz , S (3.35) α∈j where Zα∗ is now the bulk Born effective charge associated with the atom α. Again, pZ j are ill-defined in perovskite materials, as typically individual oxide layers do not satisfy the acoustic sum rule separately. To address this issue, we perform an analogous averaging procedure and define 1 Z 1 Z 1 Z p̄Z j = pj−1 + pj + pj+1 . 4 2 4 (3.36) The approximate local polarization then immediately follows, 2 . PjZ = p̄Z c j (3.37) Such an approximation provides an exact estimate, in the linear limit, of the polarization induced by a small polar distortion under short-circuit electrical boundary conditions, i.e. assuming that the macroscopic electric field vanishes throughout the structural transformation. Neither of these conditions is respected in a ferroelectric capacitor, where the polar distortion is generally large (close to the spontaneous polarization of the ferroelectric insulator), and where there is generally an imperfect screening regime, with a macroscopic “depolarizing field” [53]. Both issues have been investigated by M. Stengel in Ref. [105] (discussion included in Appendix B), where it is found that a simple scaling factor corrects, to a large extent, the discrepancy between Pj and PjZ . In particular, the “corrected” P̃jZ can be written as P̃jZ χ∞ = 1+ PjZ , χion (3.38) where χ∞ and χion are, respectively, the electronic and ionic susceptibilities of the bulk material in the centrosymmetric reference structure, calculated at the same in-plane strain as the capacitor heterostructure. Note that for a ferroelectric material in the centrosymmetric reference structure, χion is negative, which is a consequence of the polar unstable mode in the phonon spectrum. This means that the scaling factor will be smaller than 1 (∼0.9 for the materials considered in this work). Practical methods to calculate χ∞ and χion are reported in Appendix B. 3.3. Methods 3.3.3 73 Constrained-D calculations In Sec. 3.2 we have shown that a pathological spill-out regime can be triggered by the ferroelectric displacement D of the film, as the band offset generally strongly depends on D. It is therefore important, in order to perform the analysis described in the previous Sections, to calculate the electronic and structural ground state of a metal/ferroelectric interface at different values of D. To this end, two different approaches can be used in first-principles calculations. The first, and more “traditional” approach, involves the construction of capacitor of varying thicknesses t, and the relaxation of the corresponding ferroelectric ground states within short-circuit boundary conditions. Due to the interface-related depolarizing effects mentioned in Sec. 3.2 (these are strongest in thinner films and tend to reduce P from the bulk value Ps ), the polarization will increase from P = 0 (for t < tcrit , where tcrit is the “critical thickness” [47, 53]) to P ∼ Ps , in the limit of very large thicknesses. Due to the small value of the vacuum permittivity ε0 , for typical values of the polarization in a ferroelectric material, ε0 E P , and D ∼ P , meaning that the variation of the polarization can be identified with a variation of D. (Throughout this Chapter we shall make use of this identity, and talk about either P or D.) This might be cumbersome in practice: thicker capacitor heterostructures imply a substantial computational cost, due to the larger size of the system; this severely limits the range of P (D) values that can be studied within short-circuit boundary conditions. An alternative, more efficient methodology to explore the electrical properties of the interface as a function of polarization, is to use the recently developed techniques to constrain the macroscopic electric displacement to a fixed value. [51, 52] With this method, one is able, in principle, to access at the same computational cost the structural and electronic polarization of the capacitor for an arbitrary polarization state. In the specific context of the present work, however, there are two drawbacks related to the use of the constrained-D method as implemented in Refs. [51] and [52]. First, fixed-D strategies make use of applied electric fields to control the polarization of the system. This is a problem here, where the metallicity associated with the space charge which populates the ferroelectric film makes such a solution problematic. (If a capacitor becomes metallic, it is a conductor and no metastable polarized state can be defined at any given bias.) Second, our philosophy in this work is to adopt “standard” computational techniques, i.e. those that are in principle available in any standard electronic structure package. To this end, an alternative way of performing constrained-D calculations for a metalinsulator interface has been suggested by M. Stengel, which does not rely on the direct application of macroscopic electric fields or on the calculation of the macroscopic Berryphase polarization. According to this method a vacuum/ferroelectric/metal geometry is adopted, as sketched in Fig. 3.9(b). To induce a given value of the polarization in the ferroelectric film, a layer of bound charges (Q per surface unit cell S) is introduced at its free surface. If this is done in such a way that the surface region remains locally insulating, at electrostatic equilibrium, the difference in the macroscopic displacement D on the left and on the right side of the surface will exactly correspond to the additional surface charge density Q/S. By applying a dipole correction in the vacuum region, we 74 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors (a) (b) σ =P + + + + + + + + + + + + + + Conduc tion ban d E F (1) E F (2) Valence Metal band P Ferroelectric E F (2) P Metal Vacuum Ferroelectric Metal Figure 3.9: Two alternative ways of simulating a metal/insulator interface at a given value of the macroscopic electric displacement D. (a) Capacitor heterostructure with a finite applied field using the methods of Ref. [87]. (b) Vacuum/Insulator/Metal heterostructure with an external bound charge density σ = D applied to the open surface of the insulating film; the electrostatic potential in the vacuum region is assumed to be flat (in practice this is achieved by applying a dipole correction) . ensure that D = 0 in the region near the surface on the vacuum side; then on the insulator side we have exactly Q D= . (3.39) S In practice, the additional charge density is introduced by substituting a cation at the ferroelectric surface by a fictitious cation of different formal valence. For example, by terminating a PbTiO3 film with a NbO2 layer (of formal charge +1), we would induce a polarization in the PbTiO3 film of about 1 C/m2 ; a termination with ZrO2 , on the other hand, would enforce D = 0 everywhere. As we are interested in exploring intermediate values of D, the virtual crystal approximation is used to effectively induce a fractional nuclear charge. The reader might have noted that this method to control D is just a generalization of Eq. 3.13 to consider other forms of “external” charge that are not “free” in nature. Indeed, in the most general case, one can state ∇D = ρext (r), (3.40) where D encompasses all bound-charge effects that can be referred to the properties of a periodically repeated primitive bulk unit, and ρext contains all the rest (e.g., delta-doping layers, metallic free charges, charged adsorbates, variations in the local stoichiometry, etc.). In Eq. 3.39 we simply applied Eq. 3.40 to the vacuum/ferroelectric interface, where the “bound” nature of the external charge allows us to control it as an external parameter. 3.3. Methods 3.3.4 75 Computational parameters To demonstrate the generality of our arguments, which are largely independent of the fine details of the calculation (except for the choice of the density functional), we compare simulations performed with two different DFT-based electronic structure codes, Siesta and Lautrec. In both cases, the interfaces where simulated by using a supercell approximation with periodic boundary conditions. [84] A (1×1) periodicity of the supercell perpendicular to the interface is assumed. This inhibits the appearance of ferroelectric domains and/or tiltings and rotations of the O octahedra. A reference ionic configuration was defined by piling up m unit cells of the perovskite oxide (PbTiO3 , BaTiO3 or KNbO3 ), and n unit cells of the metal electrode (a conductive oxide such as SrRuO3 or a transition metal such as Pt). In order to simulate the effect of the mechanical boundary conditions due to the strain imposed by the substrate, the in-plane lattice constant was fixed to the theoretical equilibrium lattice constant of bulk SrTiO3 (a0 = 3.874 Å for Siesta and a0 = 3.85 Å for Lautrec). To simulate the capacitors in an unpolarized configuration in Sec. 3.4, we imposed a mirror symmetry plane at the central BO2 layer, where B stands for Ti or Nb, and relaxed all the atomic coordinates and out-of-plane strain of the tetragonal supercells within P 4/mmm symmetry. For the ferroelectric capacitors described in Sec. 3.5 a second minimization was carried out, with the constraint of the mirror symmetry plane lifted. Tolerances for the forces and stresses are 0.01 eV/Å and 0.0001 eV/Å3 , respectively. Other computational parameters, specific to each code, are summarized below. Siesta Computations in Sec. 3.4.1 and 3.5.1 on short-circuited SrRuO3 /PbTiO3 and SrRuO3 / BaTiO3 capacitors have been performed within a numerical atomic orbital method, as implemented in the Siesta code [121]. Core electrons were replaced by fully-separable [122] norm-conserving pseudopotentials, generated following the recipe given by Troullier and Martins [123]. Further details on the pseudopotentials and basis sets can be found in Ref. [124]. A 6 × 6 × 1 Monkhorst-Pack [90, 113] mesh was used for the sampling of the reciprocal space. A Fermi-Dirac distribution was chosen for the occupation of the one-particle Kohn-Sham electronic eigenstates, with a smearing temperature of 0.075 eV (870 K). The electronic density, Hartree, and exchange-correlation potentials, as well as the corresponding matrix elements between the basis orbitals, are computed in a uniform real space grid, with an equivalent plane-wave cutoff of 400 Ry in the representation of the charge density. Lautrec Calculations in Sec. 3.4.2 and 3.5.2 were performed by Massimiliano Stengel with Lautrec, an “in-house” plane-wave code based on the projector-augmented wave method [125]. He used a plane-wave cutoff of 40 Ry and a 6 × 6 × 1 Monkhorst-Pack [90, 113] 76 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors mesh. As the systems considered here are metallic, a Gaussian smearing of 0.15 eV was adopted to perform the Brillouin-zone integrations. 3.4 3.4.1 Results: Non polar capacitors Non-pathological cases In the centrosymmetric unpolarized reference structure, some metal/ferroelectric interfaces such as BaTiO3 /SrRuO3 or PbTiO3 /SrRuO3 with a TiO2 /SrO termination [the properties of the alternative (Ba,Pb)O/RuO2 termination might differ] are “wellbehaved” within LDA. This conclusion emerges from the analysis shown in Fig. 3.10 and 3.11 for the PbTiO3 - and BaTiO3 -based capacitors respectively. Figures 3.10(a) and 3.11(a) represents schematically the Schottky barriers for electrons (φn ) and holes (φp ) at the ferroelectric/metal interfaces, computed using the nanosmoothed electrostatic potential method described in Sec. 3.3.1. The bottom of the conduction band of the ferroelectric lies, in both cases, above the Fermi level of the metal (φn amounts to 0.38 eV for the PbTiO3 -based capacitor, and only to 0.19 eV in the BaTiO3 -based case). Note that, if the experimental band gap could be reproduced in our simulations, φn would be much larger [dashed lines in Fig. 3.10(a) and 3.11(a); we have taken the experimental indirect gap of the cubic phase of PbTiO3 , 3.40 eV [126], and BaTiO3 , 3.20 eV [127]; and assumed that the quasiparticle correction on the valence band edge is negligible]. The results summarized in Table 3.2 illustrates some important issues commented in 3.3.1. Results based on the nanosmoothed electrostatic potential and on the method combining supercell and bulk LDOS calculations, yield Schottky barrier values that are consistent within few hundredths of an eV, in accordance with the fundamental equivalence of these two approaches. Estimations based on the PDOS alone, however, results in larger values due to the absence of the high symmetry k-points in the calculations. The flatness of the profile of the nanosmoothed electrostatic potential at the central layers of the ferroelectric in Fig. 3.10(a) and 3.11(a) confirms the absence of any macroscopic electric field, as expected from a locally charge-neutral and centrosymmetric system. Figures 3.10(b) and 3.11(b) displays ρ̄free (z), as defined in Sec. 3.3.2. As expected, ρ̄free (z) has a rapid decay in the insulating layers, consistent with the evanescent character of the metallic states (MIGS): these cannot propagate in the insulator as their energy eigenvalue fall within the forbidden band gap. In agreement with the positive values of the Schottky barriers, except at the region very close to the interface where MIGS still have some weight, an absolute abscence of free charge is found in the insulating region. Figures 3.10(c) and 3.11(c) shows the layer-by-layer polarization, PjZ , computed using Eqs. (3.35)-(3.37). Consistently with the absence of space charge, the PjZ profile is remarkably flat. Due to the imposed mirror-symmetry constraint, PjZ also vanishes inside the ferroelectric materials. Finally, Fig. 3.12 shows, for the PbTiO3 /SrRuO3 capacitor, the layer-resolved PDOS 77 3.4. Results: Non polar capacitors 1.0 8 0.8 -3 EF = +8.91 eV 0.4 (b) 0.4 2 (a) 0.2 0 -0.2 -0.4 (c) TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 SrO RuO2 SrO RuO2 SrO RuO2 SrO -2 0.6 0.2 P (C/m ) 0 EC = +5.94 eV 2 ∆<V> = 3.34 eV 4 φp = 0.97 eV EV = +4.59 eV Energy (eV) 6 -3 φn = 0.38 eV ρfree (10 e Bohr ) 10 Figure 3.10: (a) Schematic representation of φn and φp in an unpolarized SrRuO3 /PbTiO3 /SrRuO3 capacitor. EV , EC , EF and ∆hV i were defined in Sec. 3.2. The calculated values are also indicated in the Figure. The black solid curve represents −V H (z). The dashed line represents the hypothetical position of the CBM, if EC were shifted as to reproduce the experimental band gap. (b) Profile of ρ̄free as defined in Eq. (3.31). (c) Profile of the layer-by-layer polarization PjZ . The size of the capacitor corresponds to n = 5.5 unit cells of SrRuO3 and m = 12.5 unit cells of PbTiO3 . Only the top half of the symmetric supercell is shown. 78 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors 1.0 10 φn= 0.19 eV 0.8 -3 ρfree (10 e Bohr ) 8 φp= 1.39 eV 0.6 (b) 0.4 0 -0.2 SrO SrO RuO2 SrO RuO2 BaO TiO2 SrO RuO2 BaO TiO2 (c) BaO TiO2 -0.4 BaO TiO2 2 (a) 0.2 BaO TiO2 -2 0.4 0.2 P (C/m ) 0 EF= +8.90 eV 2 EC= +7.29 eV EV= +5.71 eV 4 ∆V= 1.79 eV Energy (eV) -3 6 Figure 3.11: (a) Schematic representation of φn and φp in an unpolarized SrRuO3 /BaTiO3 /SrRuO3 capacitor. EV , EC , EF and ∆hV i were defined in Sec. 3.2. The calculated values are also indicated in the Figure. The black solid curve represents −V H (z). The dashed line represents the hypothetical position of the CBM, if EC were shifted as to reproduce the experimental band gap. (b) Profile of ρ̄free as defined in Eq. (3.31). (c) Profile of the layer-by-layer polarization PjZ . The size of the capacitor corresponds to n = 5.5 unit cells of SrRuO3 and m = 8.5 unit cells of BaTiO3 . Only the top half of the symmetric supercell is shown. 79 3.4. Results: Non polar capacitors Table 3.2: LDA values of φn and φp , obtained with the three different methods described in Sec. 3.3.1: using the edges of the PDOS calculated over the central TiO2 layer (PDOS), using the decomposition into EV,C and ∆hV i (BS + Lineup), and using Ti (3s) semicore states to align bulk band structure to the density of states of the capacitor (Semicore). Methods including high-symmetry (HS) k-points are indicated. Capacitor SrRuO3 /PbTiO3 /SrRuO3 φp φn SrRuO3 /BaTiO3 /SrRuO3 φp φn PDOS (no HS) BS + Lineup (HS) Semicore (HS) 1.28 0.53 0.97 0.38 0.99 0.37 1.55 0.42 1.39 0.19 1.40 0.19 of the Ti(3s) semicore peaks, the O(2s) peak, the upper valence band and the lower conduction band (black curves, shaded in gray). On top of the heterostructure PDOS we superimpose the bulk PbTiO3 PDOS, calculated with an equivalent k-point sampling and aligned with the Ti(3s) peak (dashed red curves). Note that all PDOS curves were calculated using Eq. (3.27), and the smearing function gFD of Eq. (3.28b) with σ = 0.075 eV, consistent with the parameters used in the calculation. The PDOS of the conduction and valence bands converges fairly quickly to the bulk curve when moving away from the interface – they are practically indistinguishable already at the fourth layer. The estimated energy location of the conduction and valence bands converge even faster [these are directly related to the shifts of the Ti(3s) state, which are less affected by quantum confinement effects]. All curves except those adjacent to the electrode interface vanish at the Fermi level, confirming the absence of charge spill-out in this system. As a summary of this Section we can conclude that, when a centrosymmetric unpolarized interface is non-pathological in the sense that the bottom of the conduction band of the ferroelectric is above the Fermi level of the metal, (i) the free charge, as defined in Sec. 3.3.2, vanishes due to the absence of charge spill-out; (ii) the local polarization profile (Sec. 3.3.2) is perfectly flat as the interface-induced polar lattice distortions heal rapidly (within the first unit cell); and (iii) the LDOS/PDOS vanishes at the Fermi level, except for one or two interface layers where the signatures of the MIGS are still present. 3.4.2 Pathological cases We analyze now two examples of capacitors that are characterized by a pathological band alignment already in their centrosymmetric reference structure: NbO2 -terminated KNbO3 /SrRuO3 , and TiO2 -terminated BaTiO3 /Pt. This choice of materials is motivated by the fact that there exist recent theoretical works on these systems, [128, 129] PDOS (arb. units) 80 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors -57.6 -57.2 -56.8 -20 -18 -16 -4 -3 -2 -1 0 1 2 3 Energy (eV) Figure 3.12: PDOS of the inequivalent TiO2 layers in the unpolarized PbTiO3 /SrRuO3 capacitor (solid curves with gray shading). The bottom curve lies next to the electrode, the top one lies in the center of the PbTiO3 film. Only the PDOS on half of the symmetric supercell are shown. Panels show from left to right, Ti (3s) states, O (2s) states and band gap energy region. The bulk PDOS curves (red dashed) are aligned to match the Ti(3s) peak at E ∼ −57 eV. The Fermi level is located at zero energy and marked as a dotted line. where the consequences of the pathological band alignment were neglected. Calculations presented in this Section were carried out by M. Stengel and are included here for the completeness of the discussion. KNbO3 /SrRuO3 We construct a heterostructure consisting of m=6.5 KNbO3 unit cells and n=7.5 SrRuO3 cells, for a total of 14 perovskite units; we use symmetrical NbO2 (SrO) terminations of the KNbO3 (SrRuO3 ) film. After full relaxation with a mirror symmetry constraint at the central NbO2 layer, we perform the analysis of the LDOS, the conduction charge and the local polarization as explained in Sec. 3.3. In Fig. 3.13 we show the local density of states integrated over the NbO2 layers The unphysical Ohmic band alignment is evident from the location of the conduction band bottom – the whole film is clearly metallic. This points to the pathological situation that is sketched in Fig. 3.1(g). Note that the LDOS does not converge to the bulk curve anywhere in the heterostructure. There are non-trivial shifts of all peaks that make it 81 LDOS (arb. units) 3.4. Results: Non polar capacitors -56 -20 -19 -18 -17 -8 -7 -6 -5 -4 -3 -2 -1 0 1 2 3 Energy (eV) Figure 3.13: LDOS integrated over the NbO2 layers of the KNbO3 /SrRuO3 heterostructure (solid curves with gray shade). The bottom curve lies next to the electrode, the top one lies in the middle of the KNbO3 film. Only the LDOS on half of the symmetric supercell are shown. Panels show from left to right, Nb (4s) states, O (2s) states and band gap energy region. The bulk LDOS (red dashed curves) are aligned as to match the valence and conduction band edges. The Fermi level is located at zero energy and marked with a dotted line difficult to identify a well-defined alignment with the bulk curves. In Fig. 3.13 we choose to align the O(2s)-derived feature at E ∼ −19 eV. In this specific system, aligning the O(2s) peaks appears to yield a reasonably good match of the conduction and valence band edges (the most relevant features from a physical point of view); this, however, leads to a marked mismatch, e.g. in the position of the semicore Nb(4s) state. We show in the following that these effects stem from a number of (rather dramatic) electrostatic and structural perturbations acting on the KNbO3 film, which are a direct consequence of the pathological band alignment. First we show that this misalignment results in a sizeable spill-out of conduction charge into the ferroelectric film. To that end, we plot ρfree (z), which represents the planar average of the artificially populated part of the KNbO3 conduction band, and the corresponding nanosmoothened version, ρfree (z) in Fig. 3.14 respectively as black continuous and red dashed lines. The additional electron density in the ferroelectric region is apparent [compare the scale of the plot with that of Fig. 3.10(b)], and reaches a maximum of about 0.15 electrons in the central perovskite unit cell. Such a density is significant – it can be thought as resulting from an unrealistically large doping of, 82 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors 1.2 -3 0.8 -3 ρfree [10 e bohr ] 1.0 0.6 0.4 NbO2 KO NbO2 KO NbO2 KO NbO2 KO NbO2 KO NbO2 NbO2 0.0 KO 0.2 Figure 3.14: Calculated free charge for paraelectric SrRuO3 /KNbO3 /SrRuO3 heterostructure. Black curve: planar-averaged ρfree . Red dashed: ρfree , nanosmoothened using a Gaussian filter. Blue symbols: finite differences of the local Pj (shown as a black curve in Fig. 3.15), calculated using the Wannier-based layer polarization described in Sec. 3.3.2. e.g. one Sr2+ cation every six or seven K+ ions. However, unlike in a doped perovskite, the spurious electron spill-out here is not compensated by an appropriate density of heterovalent cations. The system is therefore not locally charge neutral, and as a consequence strong, non uniform electric fields arise in the insulating film that act on the ionic lattice. In order to elucidate how the underlying polarizable material responds to such an electrostatic perturbation, we plot in Fig. 3.15 the effective polarization profile in the KNbO3 film calculated in two ways, (i) the rigorous Wannier-function analysis of the layer polarizations and (ii) the approximate expression based on the renormalized bulk dynamical charges. The matching between the curves is excellent, indicating that the approximate Z ∗ -based formula provides a reliable estimate of P (z); this suggests that the electrostatic screening is indeed dominated by structural relaxations [see also Fig. 3.16], as anticipated in Sec. 3.2.2, and as expected in a ferroelectric material. The polarization profile Pj is characterized by a uniform, negative slope. This nicely confirms the prediction of our semiclassical analysis in Sec. 3.2.2 of a uniform linear decrease of D(z) throughout the film. [Recall that the difference between P and D is negligible in KNbO3 , of the order of 1% or less, which justifies our use of P (z) in place of D(z) in the differentiation.] Pj varies from 0.3 to -0.3 C/m2 when moving from the bottom to the top interface Note that such spatial variation is completely absent in, e.g., isostructural paraelectric BaTiO3 /SrRuO3 (Fig. 3.11(c) and diamonds in Fig. 3.15), and PbTiO3 /SrRuO3 [Fig. 3.10(c)] capacitors, where the profile is remarkably flat with P 83 3.4. Results: Non polar capacitors 0.2 2 Polarization [C/m ] 0.4 0 AO BO2 AO BO2 AO BO2 AO BO2 AO BO2 -0.4 AO -0.2 Figure 3.15: Local polarization profile in the SrRuO3 /KNbO3 /SrRuO3 capacitor. Black circles: polarization from Wannier-based layer polarizations. Red squares: approximate polarization from “renormalized” Born effective charges (see Sec. 3.3.2). Analogous results for a paraelectric SrRuO3 /BaTiO3 /SrRuO3 capacitor are shown for comparison (blue diamonds). vanishing throughout the film. To demonstrate that the spatial variation in P (z) is directly related to ρfree according to Eq. (3.13), we perform a numerical differentiation of the polarization profile derived from the Wannier-based layer polarizations (again making use of the small difference between P and D). The result, plotted in Fig. 3.14 as a blue line, shows an essentially perfect match between dP/dz and −ρfree illustrating the fact that the polarization profile is really a consequence of KNbO3 responding to the spurious population of the conduction band, rather than of interface bonding effects [128]. Finally, to illustrate the role of the lattice relaxation in the screening of the excess charge, we also compare in Fig. 3.16 the relaxed layer rumplings in KNbO3 /SrRuO3 to those of the non-pathological case, PbTiO3 /SrRuO3 , discussed in Sec. 3.4.1. The KNbO3 film is characterized by strong non-homogeneous distortions, which are at the origin of the polarization pattern shown in Fig. 3.15. Conversely, the distortions are negligible in the PbTiO3 /SrRuO3 capacitor, where all the oxide layers are essentially flat. This striking qualitative difference is a strong evidence that the perturbation experienced by KNbO3 /SrRuO3 , which affects the whole volume of the film, is of different physical nature than the localized interface bonding effects in BaTiO3 /SrRuO3 or PbTiO3 /SrRuO3 . We note that this behavior is also qualitatively different from a ferroelectric distortion, which involves a rigid displacement of the ionic sublattices, and preserves a macroscopically uniform rumpling pattern across the film [52]. 84 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors Layer rumpling (Å) 0.2 0.1 0 -0.1 -0.2 -10 -5 0 Layer index 5 10 Figure 3.16: Layer rumplings (cation-oxygen vertical relaxations) in the centrosymmetric KNbO3 /SrRuO3 (black line, empty circles) and PbTiO3 /SrRuO3 (red line, filled circles) capacitors. Dashed vertical lines indicate the location of the BO2 planes. The shaded areas correspond to the SrRuO3 electrode region. BaTiO3 /Pt We next present results of an analogous investigation for a paraelectric (BaTiO3 )m /(Pt)n capacitor, with m = 8.5 and n = 11. We consider symmetric TiO2 terminations, with the interfacial O atoms in the on-top positions. (Note that this interface structure is different than the AO-terminated films simulated, e.g. in Refs. [52] and [47], where a Schottky-like band offset was found.) We find this interface to have a pathological band alignment, similar to the KNbO3 /SrRuO3 case discussed above. The comparative analysis of the bound-charge polarization profile and of the excess conduction charge, shown in Fig. 3.17, again shows excellent agreement between ρ̄¯free (z) and the compensating bound charge. The effect is analogous to KNbO3 /SrRuO3 , with an overall magnitude which is smaller by roughly a factor of two; the polarizations at the two extremes of the film reach values of about ±0.15 C/m2 . The almost perfect similarity in behavior between these two chemically dissimilar systems is further proof that the unusual effects described here and in Ref. [128] – the apparent head-to-head domain wall in the ferroelectric film – have little to do with the bonding at the interface, but are merely a consequence of the artificial charge spill out, as discussed in Sec. 3.2. 85 3.4. Results: Non polar capacitors 0.6 0.2 (a) (b) 0.1 2 Polarization [C/m ] -3 0.4 -3 ρfree [10 e bohr ] 0.5 0.3 0.2 0.0 -0.1 TiO2 TiO2 TiO2 TiO2 TiO2 TiO2 -0.2 TiO2 TiO2 TiO2 TiO2 TiO2 TiO2 TiO2 0.0 TiO2 0.1 Figure 3.17: (a) Calculated free charge and (b) local polarization profile for a paraelectric Pt/BaTiO3 /Pt capacitor with TiO2 -type interfaces. All symbols have the same meaning as in Fig. 3.14 and Fig. 3.15. Physical nature of the conduction charge in pathological band alignments Before moving on to the next Section we briefly comment on the physical nature of the conduction charge that spills into the ferroelectric film. In particular, it is important to clarify that the charge densities plotted in Fig. 3.14 and Fig. 3.17(a) indeed originate from population of the conduction band of the insulator, and not from metal-induced gap states (MIGS) as some authors have recently argued [130]. All our data unambiguously point to the former hypothesis. First, all charge density plots show a maximum in the middle of the ferroelectric layer, rather than a minimum, which one would expect if the former hypothesis were true, given the evanescent character of the MIGS. Second, the individual wavefunctions that contribute most to ρfree in the ferroelectric film appear to be confined within the insulator, that is they have almost no weight in the electrode region. Therefore, we must conclude that these are genuine conduction band states, and not MIGS. The maximum of ρ̄¯free in the middle of the ferroelectric film can be interpreted either as a quantum confinement effect [the lowest-energy solution of the electron-in-a-box problem is indeed a sine function with a shape reminiscent of the ρ̄¯free plots of Fig. 3.14 and Fig. 3.17(a)], and/or as a result of the dielectric nonlinearities discussed in Sec. 3.2.3 and depicted schematically in Fig. 3.8. This picture is fully consistent with the LDOS of Fig. 3.13, where it is clear that there are no occupied states (i.e. MIGS) within the gap below the conduction band edge of KNbO3 . 86 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors 0.4 φn (eV) 0.2 0 -0.2 -0.4 0 0.2 0.4 0.8 0.6 Interface doping x 1 Figure 3.18: n-type Schottky barrier as a function of interface doping in KNbO3 /AOterminated SrRuO3 , where A is a fictitious atom with atomic number Z = 37 + x. Only the Sr atoms at the interfacial layer are replaced by this fictitious atom. The dashed line is a linear regresion of the data between x = 0 and x = 0.3, where the interface is non-pathological from the band alignment point of view. Blue and red empty symbols represent, respectively, the results for x = 0.5 and x = 1.0, where the interface is already pathological. All values were obtained from Eq. (3.29), using either the Nb(4s) (squares) or the O(2s) (circles) semicore peaks of the central NbO2 layer as a reference. Estimating the “pre-spill” band offset We mentioned in Sec. 3.2 that, whenever an electrode/ferroelectric interface enters the pathological spill-out regime, the transfer of charge into the conduction band of the insulator produces an upward shift of the CBM. This effect prevents a direct, unambiguous determination of the interface parameter φ0n . In Ref. [105], M. Stengel suggest an approach, inspired by a recent work [131], to circumvent this problem, and obtain an approximate estimate of the negative “pre-spill” Schottky barrier φ0n . The authors of Ref. [131] show that the Schottky barrier at the interface between a perovskite insulator (SrTiO3 ) and a perovskite electrode (La0.7 A0.3 MnO3 , where A is Ca, Sr, or Ba) evolves linearly as a function of the compositional charge of the interface layer. (Such interface layer is of the type Lax Sr1−x O, where x interpolates between a +3 and a +2 cation.) Of course, this linear behavior refers to a range of x values where the interface is non-pathological; our arguments indicate that as soon as the system enters the spill-out regime, the value of φn saturates to a nearly constant value. Based on this observation, if one knows the linear behavior of φn in a range of x values for which the interface is non-pathological, one can extrapolate this straight line to the values of x which cannot be directly calculated, and obtain an estimate for φ0n . 87 3.4. Results: Non polar capacitors (a) 0.3 (b) 0.2 1.0 2 Polarization (C/m ) -3 -3 Charge density (10 e bohr ) 1.2 0.8 0.6 0.4 0.1 0 -0.1 -0.2 0.2 -0.3 0.0 NbO2 NbO2 NbO2 NbO2 NbO2 NbO2 NbO2 NbO2 NbO2 Figure 3.19: (a) Conduction charge density, and (b) local (Wannier-based) polarization profiles extracted from the calculations with x =0.0, 0.1, 0.2 and 0.3 (filled circles, thin black curves); 0.5 (empty blue circles, dashed blue curve) and 1.0 (empty red circles, solid red curve). In (a) only half of the KNbO3 film is shown. This strategy was applied to the same KNbO3 /SrRuO3 capacitor system described Sec. 3.4.2. To tune the interface charge, the Sr cation in the interface SrO layer was replaced with a fictitious atom of fractional atomic number Z = 37+x. x = 1 corresponds to the example already shown in Sec. 3.4.2, with a charge-neutral SrO interface layer, and x = 0 corresponds to a RbO layer of net formal charge -1. The results for the Schottky barrier are plotted in Fig. 3.18. The region from x = 0.0 to x = 0.3 is non-pathological and shows an almost perfectly linear evolution of φn (dashed line). By extrapolating this linear trend to x = 1 we obtain φn ∼ −1.2 eV, which is about 1 eV lower than the value calculated from first principles. This confirms the remarkable efficiency of the self-healing mechanism. Assuming a polarization of ∼ 0.3 C/m2 for KNbO3 near the interface, a potential drop of 1 eV would be accounted for by an effective screening length of 0.3 Å at the electrode interface. This value is quite reasonable, and similar in magnitude to those reported in Table 3.1. In order to examine the crossover between the Schottky (non-pathological) and the Ohmic (pathological) regimes in terms of the analysis tools developed in this work, we plot in Fig. 3.19 the polarization profiles and the density of conduction electrons for each of the calculations summarized in Fig. 3.18. These plots confirm that from x = 0 to x = 0.3 the capacitors are non-pathological, with absence of conduction charge in the insulating region [Fig. 3.19(a), thinner black lines] and a flat polarization profile [Fig. 3.19(b), filled black circles – all these curves overlap on this scale]. Conversely, at x = 0.5 the conduction band starts populating significantly [thicker dashed blue line in Fig. 3.19(a), empty blue circles in Fig. 3.19(b), note that the point in Fig. 3.18 starts to depart from the linear regime]. At x = 1.0 population of the conduction band 88 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors has become dramatic, and so is the corresponding slope in the polarization profile. The departure from linearity in Fig. 3.18 is correspondingly large. Note that the use of either the Nb(4s) or the O(2s) semicore peaks in Eq. (3.29) yields identical results in the non-pathological regime (the filled squares and circles overlap in Fig. 3.18). Conversely, the result depends significantly on this (completely arbitrary) choice at x = 0.5, and even more so at x = 1.0 (the circles and squares split). This is another proof that in the pathological regime the band lineup is ill-defined – due to the electrostatic effects discussed throughout this work, the LDOS does not converge to a bulk-like value in the center of the KNbO3 film (see Fig. 3.13), and there is no obvious reference energy to determine the offset. 3.5 Results: Polar capacitors As discussed in the Introduction of this chapter, although some of the unpolarized reference structures (e.g. the PbTiO3 /SrRuO3 interface) appear artifact-free within LDA, because of the strong dependence of the Schottky barrier on D they might become problematic when the constraint of mirror symmetry is lifted and the system is polarized. In the spirit of the “traditional” approach to explore the band offset in ferroelectric capacitors as a function of D, we address this issue performing simulations of short-circuited capacitors for selected thicknesses of the ferroelectric layer. Results of the standard approach have been further extended by M. Stengel using the fixed-D strategy described in Sec. 3.3.3 to explore the behavior of the ferroelectric/metal interface over a wide and continuous range of polarization states. 3.5.1 Short-circuit calculations PbTiO3 /SrRuO3 We have performed simulations on [PbTiO3 ]m /[SrRuO3 ]n heterostructures, with m = 12.5 and n = 5.5 unit cells. A soft-mode distortion of the bulk tetragonal phase, inducing a polarization perpendicular to the interface, is superimposed on the PbTiO3 layers of the previous unpolarized configurations discussed in Sec. 3.4.1. Then the atomic positions of all the ions, both in the ferroelectric and in the metallic electrodes, and the out-of-plane stress are re-relaxed with the same convergence criteria as before. By means of the approximate Eq. (3.38), derived in Sec. 3.3.2, we computed the local layer-by-layer polarization, P̃jZ , plotted in Fig. 3.20 (a). Far enough from the interface, the polarization profile is rather uniform, with a polarization that amounts to 0.53 C/m2 in PbTiO3 (64 % of the strained bulk polarization), which we identify as the macroscopic P of the PbTiO3 film. The uniform value of the polarization inside the ferroelectric layer breaks up in the region adjacent to the top electrode [right end of curve in Fig. 3.20 (a)]. As we will se below, the origin of this inhomogeneous distortion can be traced back to a pathological charge injection, in analogy to the centrosymetric case discussed in previous section. 89 3.5. Results: Polar capacitors (a) 2 P [C/m ] 0.8 0.6 RuO2 SrO RuO2 SrO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 SrO RuO2 SrO RuO2 SrO RuO2 SrO 0.4 0.5 (b) -3 ρfree [10 e Bohr ] 0.4 -3 0.3 0.2 RuO2 SrO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 TiO2 0.0 PbO 0.1 Figure 3.20: (a) Profile of the layer-by-layer polarization P̃jZ , defined in Eq. (3.38), in the relaxed polar configuration of a short-circuited SrRuO3 /PbTiO3 /SrRuO3 capacitor. The dashed line represents the bulk spontaneous polarization under the same in-plane strain as in the capacitor. (b) ρ̄free (z) as defined in Eq. (3.31) (black solid line), and its nanosmoothened average ρ̄¯free (z) (red dashed line). The blue line represents the profile of the bound charge, computed as a finite-difference derivative of P̃jZ . After transforming the dipole density of the layers to local polarization by means of Eq. (3.37), we can infer a value of d ∼ 0.5, where d = DS is the reduced macroscopic displacement field [51]. The band alignment for the relaxed polar capacitor is obtained plotting the layerby-layer PDOS, shown in Fig. 3.21. The curves were constructed exactly as in Fig. 3.12, except that (i) the capacitor is now polarized; and (ii) consistent with the discussion of Sec. 3.3.1 we set up the bulk reference calculation by using the PbTiO3 structure extracted from the central layer of the polarized supercell (i.e. with atomic distortions and out-of-plane strain consistent with a polarization of 0.53 C/m2 ). The agreement is again very good, showing that our approximation of neglecting the macroscopic depolarizing field in the bulk reference calculation is reasonable, and that the most important effect PDOS (arb. units) 90 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors -58 -57 -56 -20 -18 -16 -4 -3 -2 -1 0 1 2 3 Energy (eV) Figure 3.21: Layer by layer PDOS on the TiO2 layers of the polar SrRuO3 /PbTiO3 /SrRuO3 ferroelectric capacitor. Meaning of the lines corresponding to the PDOS curves as in Fig. 3.12, but now the PDOS on all the TiO2 layers are plotted (there is no mirror symmetry plane any more). The conduction and valence band edges are plotted as empty squares, and the dashed lines correspond to the extrapolation of such edges into the pathological region. on the PDOS originate from the lattice distortions. In the capacitor we clearly distinguish two regions. In the lower part of the PbTiO3 film, the PDOS at the Fermi level vanishes (bottom panels in Fig. 3.21), which implies that the system is locally insulating. Furthermore, the PDOS in each layer appears rigidly shifted with respect to the neighboring two layers, consistent with a tilting of the PbTiO3 Kohn-Sham eigenstates due to the the presence of a depolarizing field. In this region the sloping of the bands (-0.0286 eV/Å) is found to match reasonably well the value of the electric field obtained from the nanosmoothed electrostatic potential V H (z) (-0.0278 eV/Å, shown in Fig. 3.22). In the upper region, however, close to the top electrode, the PDOS crosses the Fermi level and the system is locally metallic. All these features are in full agreement with the scheme drawn in Fig. 3.7. In Fig. 3.21 we also plot the estimated band edges for each layer, EV,C (j) (empty 3.5. Results: Polar capacitors 91 Energy (eV) 1.0 0.5 0.0 -0.5 SrO RuO2 SrO RuO2 SrO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 SrO RuO2 SrO RuO2 SrO RuO2 SrO -1.0 Figure 3.22: Nanosmoothed electrostatic potential across the polar SrRuO3 /PbTiO3 /SrRuO3 ferroelectric capacitor. The depolarizing field can be extracted from the slope of the nanosmoothed potential in the central layer of the PbTiO3 . squares in Fig. 3.21), obtained from Eq. (3.29). We used the semicore Ti(3s) peak at each layer as Esc (j), and we calculated the bulk contribution in Eq. (3.29) from a non-self-consistent bulk calculation (based on the ground state charge density of the bulk reference calculation at P = 0.53 C/m2 described above) that included the highsymmetry k-points. The band edges calculated by this procedure are only plotted for those atomic layers where the calculation of the Schottky barriers are meaningful, namely those layers out of the pathological region and sufficiently far from the interface. The resulting data points lie very accurately on a straight line. By extrapolating this straight line (black dashed line in Fig. 3.21), we see that it crosses the Fermi level near the fourth PbTiO3 cell from the top electrode interface. This illustrates the pathological character of the band alignment in this system, consistent with the model of Fig. 3.7. The population of the conduction band in the region close to the upper interface in Fig. 3.21 is confirmed when we analyze the spatial distribution of the free charge density. The planar average of ρfree (r) for the relaxed polar configuration is plotted in Fig. 3.20(b). The existence of a charge populating the Ti 3d orbitals is evident from the peaks of ρ̄free (z) at the TiO2 layers, which are detectable up to five unit cells away from the interface. In contrast with the result for the pathological centrosymmetric capacitors where the conduction charge concentrated in the middle of the “insulating” layer, for 92 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors the polar capacitors ρfree is confined in a region close to the interface due to the internal field in PbTiO3 . As we already anticipated in the previous Sections, spurious population of the conduction band and is responsible for non-trivial lattice relaxations, which act as to screen the electrostatic perturbation. Fig. 3.20(a) indeed shows a small bending of the local polarization profile, starting roughly four unit cells away from the top interface and with a negative slope of the local polarization, P̃jZ . From classical electrostatics [Eq. (3.13)], a divergence of P̃jZ produces net bound charges, whose magnitude can be estimated by numerical differentiation of the polarization profile. The resulting profiles are shown in the red curves of Fig. 3.20(b). As in the SrRuO3 /KNbO3 /SrRuO3 unpolarized case (see Fig. 3.14), the bound charge almost perfectly cancels the conduction charge (nanosmoothed profile of ρfree ). BaTiO3 /SrRuO3 We have performed similar calculations for a polarized BaTiO3 /SrRuO3 capacitor, and found a very similar scenario. In this case the capacitor consisted of a layer of the ferroelectric material with a thickness of 8.5 unit cells sandwiched between a electrodes 5.5 unit cells thick. As in the previous case, the polar ground state is found after breaking the symmetry of a non polar configuration and relaxing. Computational parameters are the same as in previous calculations. Polarization inside the ferroelectric layer amounts to 0.32 C/m2 (80% of bulk value for BaTiO3 strained to the SrTiO3 in-plane lattice constant). The absolute value of the polarization in this system is significantly smaller than the one of PTO/SRO capacitor, nevertheless, due to the small value of φn found in the paralectric configuration (see Table 3.2), it is sufficient to cause the artificial breakdown of the capacitor. Analysis of the layer-by-layer PDOS (Fig. 3.23) analogous to that performed in the case of a PbTiO3 /SrRuO3 capacitor, shows that the conduction band crosses the Fermi level at about three unit cells from the top interface. A zoom over the curve corresponding to the TiO2 layer closest to the interface [Fig. 3.23(i)] reveals that the interface PDOS is significantly larger than the bulk one, indicating that the main contributions to the PDOS at this position and in this energy window is due to the MIGS. On the second TiO2 layer, on the contrary, the PDOS of the capacitor lies below the bulk one reflecting the fact that not only the weight of the MIGS is already negligible but that the conduction band is being pushed upwards by the spurious charge spillage (see Fig. 3.13, where the bulk semicore peaks are lowered with respect to those of the supercell when the LDOS is aligned using the band edges, and recall that in 3.23 the bulk LDOS is being aligned with the supercell semicore states). Panel (iii), corresponding to the third TiO2 layer from the interface, still shows some density of states from the conduction band below the Fermi level. At the fourth TiO2 layer from the interface [panel (iv)] the effect is barely noticeable and the edge of the CB can already be considered above the Fermi level. 93 3.5. Results: Polar capacitors (a) (i) (c) (b) (ii) PDOS (arb. units) (i) (ii) (iii) (iv) (iii) (iv) -58 -57 -20 -18 -16 -4 -3 -2 -1 0 1 2 3 -0.1 0 0.1 Energy (eV) Figure 3.23: Layer by layer PDOS on the TiO2 layers of the polar SrRuO3 /BaTiO3 /SrRuO3 ferroelectric capacitor. Meaning of the lines corresponding to the PDOS curves as in Fig. 3.12. The conduction and valence band edges are plotted as empty squares and the dashed lines correspond to the extrapolation of such edges into the pathological region. Regions close to the Fermi level are zoomed in panels (i) to (iv). Each panel (i) to (iv) corresponds to the layer with the same label in panel (c), and all are plotted with the same scale. 3.5.2 Open-circuit calculations Calculations reported in previous section provides a snapshot of the dependence of the band alignment with respect to the electric displacement D in ferroelectric capacitors. The approach followed in Sec. 3.5.1, however, would be impractical in order to obtain the whole picture, since it would require the simulation of several capacitors with increasing thicknesses in order to explore a reasonable range of values of D. The tremendous computational and human effort this would involve can be greatly reduced using the method proposed by M. Stengel and discussed in Sec. 3.3.3. Within this method a vacuum/PbTiO3 /SrRuO3 heterostructure is build, as explained in Sec. 3.3.3 and depicted schematically in Fig. 3.9. The reduced macroscopic displacement field, d = DS, is controlled by substituting the Ti at the PbTiO3 /vacuum interface with a fictitious cation of atomic number Zlef t = 40 + d (i.e. Zr for d=0). To keep an integer total number of electrons, the free end of the SrRuO3 lattice is also terminated by replacing the surface Sr atom with a cation of Zright = 20 − d (i.e. Ca for d=0). This is done out of convenience, and does not have an unphysical influence on the results. As explained 94 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors 1.0 0.20 Layer polarization [10 C/m] 0.15 -9 -3 -3 0.6 0.4 0.2 0.10 0.05 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 0.00 PbO (b) SrO RuO2 SrO PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 TiO2 (a) 0.0 TiO2 ρfree [10 e bohr ] 0.8 Figure 3.24: Results for the polarized PbTiO3 /SrRuO3 interface for increasing polarization of the film. (a) planar averaged ρfree . Black, red, green and blue curves correspond to the results for d =0.20, 0.40, 0.60 and 0.74 e, respectively. The sharp peaks in ρfree correspond to the Ti ions in the PbTiO3 film. (b) layer polarizations from the Wannierbased analysis. Same color code as in (a) in Sec. 3.3.3, a dipole is applied correction in the middle of the vacuum layer to ensure that the electric field vanishes outside the material. The thickness of the PbTiO3 slab is set to 5 unit cells, and that of SrRuO3 to 4; other computational parameters for caclulations with Lautrec have been reported in Sec. 3.3.4. Four different values of d were considered: 0.2, 0.4, 0.6 and 0.74, the latter one corresponding to the ferroelectric ground state of PbTiO3 at the SrTiO3 in-plane lattice constant. In each case, we verify by examining the LDOS that the free surface remains locally insulating; therefore, the macroscopic D = d/S in the film corresponds exactly to the value enforced by the artificial pseudopotential. The evolution of ρfree and of the Wannier-based layer polarization profiles for 0.2 ≤ d ≤ 0.74 is shown in Fig. 3.24. It is apparent from the plots of ρfree that already for the smallest value of the polarization [d = 0.20, black curve in Fig. 3.24(a)] the TiO2 layer closest to the electrode has an important density of conduction electrons. This is expected, as the evanescent tails of the metal-induced gap states (MIGS) penetrate into the insulating region for some distance at any metal/insulator junction. However, these states do not propagate very far, and already at the second TiO2 layer they are barely noticeable on the scale of the plot. At d = 0.4 [red curve in Fig. 3.24(a)] the peak on the second TiO2 layer significantly increases in magnitude, and a new small peak appears at the third TiO2 layer. Analysis of the local density of states equivalent to that performed for the short-circuited capacitors (not shown) shows that these new peaks are conduction band states of PbTiO3 , rather than evanescent SrRuO3 states. The progressive increase of d stresses out the fundamental differences between the confinement of the conduction charge and the quantum-mechanical damping of the MIGS that fall in a forbidden energy 95 SrO PbO PbO PbO PbO SrO PbO PbO PbO PbO PbO PbO PbO 3.5. Results: Polar capacitors 2 Polarization [C/m ] 0.8 0.75 (a) (c) 0.7 0.65 0.6 0.55 0.5 (b) (d) 0.6 0.4 RuO2 TiO2 TiO2 TiO2 TiO2 TiO2 RuO2 TiO2 TiO2 TiO2 TiO2 TiO2 TiO2 0.0 TiO2 0.2 TiO2 -3 -3 ρfree [10 e bohr ] 0.8 Figure 3.25: Calculated results for the fully polarized PbTiO3 /SrRuO3 interface at d = 0.74. (a) local polarization from the Wannier-based layer polarizations, and (b) planar averaged ρfree (black curve), macroscopically averaged ρfree (red dashed curve), and finite differences of the polarization shown in the panel (a) (blue squares). for a m = 8-unit cell thick PbTiO3 film. Panels (c) and (d) are the corresponding figures for a m = 5-unit cell thick PbTiO3 film. The sharp peaks in ρfree correspond to the Ti ions in the PbTiO3 film. window of the insulator. We identify confinement of ρfree with the onset of the Schottky breakdown, which becomes increasingly apparent if the polarization of the film is further increased to d = 0.60 [green curve in Fig. 3.24(a).] At d = 0.74, the population of the conduction band becomes rather dramatic, and the charge distributes over the whole film. Here, the space charge is no longer confined by the depolarizing field: in the fully polarized ferroelectric state the internal field of PbTiO3 is zero. Therefore, the intrinsic carriers are only loosely bound to the interface by the band bending effect, in a way which is entirely analogous to the well-studied case of doped semiconductor interfaces. Since the dielectric permittivity of PbTiO3 is rather large, the band bending is very efficiently screened, and the distribution of charge 96 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors can reach quite far into the insulator. To demonstrate this fact, we have repeated the simulation with the same value of d=0.74, but with a thicker PbTiO3 film of 8 unit cells [Fig. 3.25 (b)]; indeed, the conduction electrons redistribute over the whole volume of the film to minimize their kinetic energy. The metalization of the fully polarized PbTiO3 film at d=0.74 can be thought as a form of “electrostatic doping” induced by spill-out of electrons from the electrode to the PbTiO3 conduction band. As in the discussion of the paraelectric capacitors, the presence of the space charge is reflected in the progressive “bending” of the layer polarization profile [Fig. 3.24(b)]. The value of d ∼ 0.5 estimated for the short-circuited PbTiO3 /SrRuO3 capacitor analyzed in previous section would yield a polarization profile intermediate between the red and green curves in Fig. 3.24(b). The similarities between spatial distribution of free charge for d = 0.4 and d = 0.6 with respect to that found in the fully relaxed short-circuited PbTiO3 /SrRuO3 capacitor (Fig. 3.21) reinforces the validity of this method. Fig. 3.24(b) illustrates a further important consequence of the charge spill-out regime, which was mentioned already in Sec. 3.2.3: in the pathological regime the dipoles that lie closest to the electrode interface may appear “pinned” to a fixed value. This is indeed the case for the TiO2 layer adjacent to the electrode, which seems to saturate at ∼ 0.08 nC/m for increasing values of D. Again, we caution against interpreting this dipole pinning effect as a robust physical result. In general, the onset of such a pathological regime has important consequences on many physical properties of the capacitor. In the following Section we shall discuss some of them. 3.6 Discussion In this Section we discuss the important aspects of our work in the context of the existing literature. The discussion is organized in several categories, corresponding to the different properties of a ferroelectric/electrode interface (or, more generally, of a perovskite material) that might be affected by the (more or less spurious) presence of free charges in the system. 3.6.1 Structural properties of the film The authors of Ref. [128] studied KNbO3 thin films placed between symmetric metallic electrodes (either SrRuO3 or Pt) under short-circuit electrical boundary conditions. In the SrRuO3 case, the layer by layer polarization pointed in opposite directions at the top and bottom interfaces for all thicknesses, creating 180◦ head to head domains walls, which were denominated interface domain walls (IDW). The physical origin of the IDW was attributed to a strong bonding between interfacial Nb and O atoms, which would induce a “pinning” of the interface dipoles to opposite values at the top and bottom electrode interfaces. Here we have demonstrated with analytical derivations and practical examples that both the inhomogeneous polarization and the “dipole pinning” effect are clear signatures 3.6. Discussion 97 of a pathological band alignment. In particular, in an unpolarized KNbO3 /SrRuO3 capacitor analogous to those simulated by Duan et al. [128], we obtain a monotonously decreasing polarization profile, from (∼0.3 C/m2 ) at the bottom interface to an opposite value of ∼-0.3 C/m2 at the top, in excellent agreement with the results of Duan and coworkers [128]. In contrast with the conclusion of Ref. [128], however, here we find that the microscopic origin of this strong inhomogeneous polarization is the spillage of charge from the metallic electrode to the bottom of the conduction band of KNbO3 , rather than a bonding effect. These findings have important consequences concerning the physical understanding of the system with regard to the relevant observables. First, the ferroelectric material becomes in fact a metal, and such a device would respond Ohmically with a large direct DC current that would make switching difficult or impossible. This questions the appropriateness of interpreting the “average” polarization of the film as a macroscopic physical quantity that can be measured in an experiment (see next Section). Second, our arguments indicate that one of the essential factors governing the equilibrium free charge distribution (and hence the spatial variation of P ) is the conduction band structure of the ferroelectric material. This ingredient is missing in the traditional Landau-Ginzburg models, e.g. those used in Ref. [128] to interpret the above data on KNbO3 /SrRuO3 capacitors, or in Ref. [130] to interpret qualitatively similar results for a electron-doped BaTiO3 /SrRuO3 interface appear unjustified. A more promising route to capturing the essential physics of the charge equilibration mechanisms appears to be the model Hamiltonian approach proposed in Ref. [110]. Extending that strategy to the case of a metal/ferroelectric interface will be an interesting subject of further research. 3.6.2 Stability of the ferroelectric state The pathological spill-out of charge has important consequences on the spontaneous polarization of a ferroelectric capacitor. To give a qualitative flavor of such an effect, we consider the case of a capacitor that is only partially metallic, i.e. there is a depolarizing field that keeps the carriers confined to the pathological side as sketched in Fig. 3.26(a). We further consider two symmetric electrodes, i.e. characterized by identical values of φ0n (that we assume positive) and λeff . Assuming a monodomain state, there are then two stable configurations, related by a mirror symmetry operation. As φ0n is positive, upon application of an electric field there will be always an insulating region in the middle of the film, i.e. the polarization can be switched without passing through a globally metallic state. To appreciate the impact of the charge spill-out on the spontaneous polarization of the film, it is useful to look at the schematic band diagram of Fig. 3.26(a), where the conduction band bottom goes below the Fermi level in proximity of the right electrode (red area). This induces metallicity in a significant portion of the film (light grey shaded area, up to the dashed line). Based on our arguments of Sec. 3.2, the charge spill-out is associated with a spatially decreasing D(z) [Fig. 3.26(b)]. This, in turn, modifies the interface potential barrier by producing a strong upward shift in energy of the conduction band edge from what one would have if D(z) were uniform and equal to the “physical” 98 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors (a) P EF φ (D2 ) φ (D1 ) M (b) FE M D D1 D2 z Figure 3.26: Schematic representation of the impact of the charge spillage on the ferroelectric stability. M are the metal electrodes, and FE is the ferroelectric film. The polarization points to the right. value D1 . This implies that the charge spill out generally reduces the depolarizing field [the “pre-spill” estimate is sketched as a thick dashed line in Fig. 3.26(a)], and hence overstabilizes the ferroelectric state. This is what one intuitively expects – population of the conduction band constitutes an additional channel for screening the polarization charge, and this cooperates with the metallic carriers of the electrode. This, however, contrasts with the conclusions of Ref. [130], where it was argued that charge leakage suppresses P by producing a ferroelectrically “dead” layer. These conclusions are based on the assumption that the physically measurable P is the average polarization, hP i, taken over the whole volume film. As the polarization is locally reduced near a pathological interface, charge spill-out indeed results in a reduced hP i. Is it justified, though, to assume that hP i is the physically relevant quantity in the capacitor? Does hP i, in other words, reflect what is experimentally measured? In an experiment one measures the time integral of the transient current density, ∆j, that flows through the capacitor during the switching process. ∆j does not relate to hP i but to the free charge accumulated at the interfaces, which in turn is the discontinuity of D at the interfaces. Under the hypothesis that at least a portion of the film remains insulating throughout switching, it rigorously follows from the modern theory of polarization [132] that ∆j = ∆D = 2|D|; D is the value of the (locally uniform) electric displacement deep in the insulating region. (We assume for simplicity that D = 0 in the paraelectric reference state.) Therefore, observing that hP i is reduced upon charge leakage does not reflect the true effect of the pathological band alignment, which is an artificial enhancement of the spontaneous P via the reduction of the depolarizing field illustrated 3.6. Discussion 99 above. A large number of works [133, 134, 135, 136] have investigated the stability of PbTiO3 -based capacitors, and it is impossible here to discuss in detail whether and how the above band-alignment issues might have affected each of them (for instance, regarding the polarization enhancements reported in Ref. [133]). We limit ourselves to observe that, due to the large spontaneous polarization of PbTiO3 , the possible consequences of having a pathological ferroelectric state need to be taken seriously into account in the analysis, as we showed for the example of SrRuO3 electrodes in Sec. 3.5. 3.6.3 Transport properties in the tunneling regime Ferroelectric capacitors have been explored as potential tunneling electroresistance devices [104], and many recent calculations focused on the calculation of the conductance by means of first-principles methods. Metallicity and spill-out of electrons is a serious potential issue in this context, as the calculated conductance can potentially be affected by the presence of space charge in the system, in a way which is difficult to predict. The recent work of Velev et al. [129] appears to be concerned by these worries, as it focuses on TiO2 -terminated Pt/BaTiO3 /Pt capacitors. Indeed, we have showed in Sec. 3.4.2 that this interface is problematic already in the centrosymmetric paraelectric case. While we have not explored the ferroelectric regime in this system, based on the imperfect screening arguments of Sec. 3.2 (the lineup depends linearly on P around the paraelectric reference phase) we expect the spill-out effect to become worse at least at one of the two interfaces when the capacitor is polarized. In fact, the metallicity of the ferroelectric film seems to be confirmed by the data presented by the authors: In Fig. 2(a-b) of Ref. [129] the conduction band minimum (CBM) of the central BaTiO3 cell appears to be degenerate or lower than the Fermi level, and in Fig. 1 of the same paper the atomic displacements of the ferroelectric phase seems to be strongly asymmetric, consistent with our speculations. While we cannot draw a definitive conclusion, our analysis highlights the crucial importance of the band alignment issue, and the necessity of performing an adequate and convincing assessment of its impact on the results (e.g. the conductance) in each case. 3.6.4 Interface magnetoelectric effects Magnetoelectricity is one of the emerging topics in oxide research. Despite the intense efforts, one of the main limiting factors still persists: bulk materials displaying a robust magnetoelectric effect are notoriously difficult to find. To work around this problem, several researchers have been looking for alternative solutions by exploring heterostructures and composite materials. An interface has a lower symmetry than either of the constituent bulk materials, and might therefore allow for physical response properties that are absent in the parent compounds. A promising route to interfacial magnetoelectric coupling that has been proposed recently [137] is mediated by charge. The polarization of the ferroelectric (or dielectric) lattice produces a bound charge at the interface, that is screened by the carriers of the metal. If these carriers are spin-polarized, 100 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors as in a ferromagnet, there will be a net change in the magnetization. It is easy to see that the band-alignment issues that we discuss in this work have direct and important implications for the calculation of the carrier-mediated interface magnetoelectric coefficient. In the pathological regime, the calculated (magnetic) response will most likely be suppressed, as the spill-out charge, rather than the spin-polarized carriers in the electrode, will screen the applied bias potential (or the ferroelectric polarization). This speculation is directly relevant for interpreting the results of Yamauchi et al. [138] on BaTiO3 films sandwiched between Co2 MnSi (Heusler alloy) electrodes. Depending on the termination, two qualitatively different behaviors were reported: the MnSi/TiO2 interface results in a pathological band alignment and a strongly non-homogeneous local polarization profile; conversely, neither is present in the capacitor with the other type of termination, which has symmetric Co/TiO2 interfaces. A very small magnetoelectric response was reported for the MnSi/TiO2 case (contrary to the Co/TiO2 case), in qualitative agreement with our arguments above. Other recent studies,[139, 140] focusing on magnetoelectric effects in thin Fe film deposited on ATiO3 (A=Ba,Pb,Sr), also reported strongly non-uniform polarization profiles in the ferroelectric film (e.g. Fig. 3 of Ref. [140]). This suggests that also the ATiO3 /Fe interface might be concerned by the band-alignment issues discussed in this work, with potential impact on the physical observables. Our analysis tools should help clarify these issues in the above systems and in the Fe/BaTiO3 /Fe capacitors of Ref. [141]. 3.6.5 Schottky barriers Direct calculations of Schottky barriers at metal/ferroelectric interfaces are, among the many useful physical properties of these junctions, those that are most directly affected by the issues we discuss here. The consequence of a pathological band alignment is that the estimated Schottky barrier is no longer a physically meaningful interface property, but is influenced by macroscopic space-charge phenomena. A rather comprehensive work on the SrTiO3 /transition metal interface was recently reported in Ref. [142]. Without going into a too detailed analysis of the results, we limit ourselves to noting that many of the reported p-type SBH for TiO2 - or SrO-terminated interfaces are very close to, or sometimes well in excess of 1.8 eV. Considering that the LDA/GGA fundamental gap of SrTiO3 is around 1.8 eV, the actual n-type SBH of the calculation (i.e. not the value corrected with the experimental band gap) is close to zero or negative. Therefore, charge spill out is a concrete and likely possibility for many of the investigated structures. Note that, contrary to the case of oxide electrodes, ideal interfaces between SrTiO3 and simple metals tend to have a smaller λeff [50]. This implies that the effects of the electrostatic reequilibration described in Sec. 3.2 might be somewhat less dramatic, and the values of the self-consistent φn closer to φ0n . This suggests that the trends and the conclusions reported in Ref. [142] are likely to be robust with respect to the issues described in this work. However, a more detailed analysis would be certainly interesting in order to assess their impact at the quantitative level. 3.7. Conclusions 3.7 101 Conclusions Due to its accuracy and efficiency, density functional theory has emerged as the method of choice for studying ferroelectric oxides from first-principles. This predominance has been reinforced since the early 1990s by the many successes achieved in the determination of the structural, energetic, piezoelectric, and dielectric properties at the bulk level. In the last few years, those efforts have evolved to address the behaviour of the functional properties in thin films and superlattices, including in same cases (for instance, in the study of ferroelectric capacitors) the presence of metal/insulator interfaces. For a reliable prediction of the functional properties of these devices, the atomic displacements, distortions of the unit cell, the electronic structure and the band gap have to be accurately described simultaneously. However, the proper DFT treatment of such interfaces is complicated by the so-called “band-gap problem”, (significant understimation of the band gaps of the Kohn-Sham electronic band structure by the standard implementations of the LDA and GGA functionals), which might produce a pathological alignment between the Fermi level of the metal and the conduction band of the insulator, thus precluding explicit DFT investigation of many systems of practical interest. In this Chapter we have provided useful guidelines to identify such a pathological scenario in a calculation by examining its main physical consequences: (i) an inhomogeneous polar distortion propagating into the bulk of the film, (ii) the film becoming partially or totally metallic due to a non-vanishing free charge, and (iii) the local conduction band edge crossing the Fermi level. The above three effects are intimately linked, and should be considered as potential artifacts of the aforementioned band-gap problem. Whenever one of these “alarm flags” is raised in a calculation, the results should be examined with great caution. A route to overcoming this limitation involves correcting the LDA/GGA bandgap while preserving the excellent accuracy of these functionals in the prediction of groundstate properties. Traditional methods to increase the band gap of insulators, like the inclusion of a Hubbard U term in the Hamiltonian, are not satisfactory in the case of a ferroelectric capacitor with a B-cation driven ferroelectricity: the application of a U to the B-cation d orbitals opens the gap, but reduces the B cation d- O p hybridization that is responsible for the ferroelectric distortion. A more promising avenue has been recently opened by Bilc et al. [78] and Wahl and coworkers, [143] using the so-called “hybrid” functionals that combine Hartree-Fock exchange and DFT. In these works the problems of previous hybrid functionals, such as the B3LYP and B1 functionals (which overestimate the volumes and atomic distortions of ferroelectric oxides even leading to supertetragonal structures, mainly due to the GGA exchange part) are overcome. In particular the B1-WC functional proposed in Ref. [78] (a combination of GGA functional by Wu and Cohen [144] with a small percentage of exact exchange) have shown to provide good structural, electronic and ferroelectric properties as compared to experimental data for BaTiO3 and PbTiO3 . Verifying the accuracy of B1-WC in interface studies appears as an interesting subject of future research. Unfortunately, the price to pay for this accuracy is the substantially 102 Chapter 3. Band alignment issues in the ab initio simulations of FE capacitors higher computational cost of B1-WC compared to LDA/GGA. In addition to the purely technical issues, our work also opens interesting avenues regarding fundamental physical concepts. For example, ferroelectricity is usually understood within the modern theory of polarization, which is only applicable in the absence of conduction electrons (i.e. in pure insulators at zero electronic temperature). It is an important fundamental question, therefore, to assess whether our understanding of ferroelectrics in terms of bound charges, polarization and macroscopic electrical quantities still applies (and to what extent) in a regime where a sizable amount of space charge is present in the system. This issue is of crucial importance also for other systems, e.g. electrostatically doped perovskites, which bear many analogies to the physical mechanisms discussed in this work. The first-principles-based modeling approach proposed in Ref. [110] appears to be a promising route to further exploring this interesting topic. Chapter 4 Metal-induced gap states in ferroelectric capacitors 4.1 Introduction When a junction between two different materials is formed, different charge rearrangements take place in order to equilibrate the chemical potential across the interface. This is a well known problem in semiconductors interfaces physics. For instance, in any textbook [145, 83] we can find discussions about PN junctions of doped semiconductors, where this charge rearrangement consists mainly in a transfer of the corresponding conducting charge carriers (holes and electrons in P and N semiconductors respectively) from one side of the interface to the other. In interfaces between non doped perfect materials different charge rearrangements become more relevant, in particular the ionic relaxations at the interface [142], compensation (screening) charge in the electrode, and charge injection via metal-induced gap states (MIGS) [102]. The latter of these mechanisms consist in the appearance of states with energies in the band gap of forbidden energies of the insulator in a metal/insulator junction, and which decay exponentially in the insulating side of the interface. All these effects together determine the interfacial dipole in heterostructures which greatly affect – and in some cases even govern – some of the functional properties of electronic devices. Typical examples of these properties are breakdown fields in capacitors or diode effect in semiconductor junctions. For this reason, theory of MIGS have received a lot of attention in the past, specially in the field of semiconductors physics [102, 146, 147, 148]. In the field of oxides, and in particular of perovskite oxides, the recent exploitation of their functionalities in heterostructures has increased the interest of MIGS in such materials. In this context MIGS have been studied specially in connection with tunnel junctions and the recent prediction [149] and experimental measurement [150] of giant magnetoresistance in magnetic tunnel junctions using ferroelectric materials for the barriers. MIGS were even used to explain the spatial distribution of 2-dimensional electron gases at the interface between two bulk insulating materials [151]. Given the leitmotiv of this thesis, namely the study of screening properties in fer103 104 Chapter 4. Metal-induced gap states in ferroelectric capacitors roelectric thin films, we deal very often with MIGS in our simulations. Some criteria to recognize these states, which in most cases can be applied to any metal/insulator interface, were discussed for metal/ferroelectric capacitors in previous Chapter. In this Chapter we aim to characterize the MIGS in ferroelectric capacitors and their connection with the complex band structure of the ferroelectric material. We study the mechanisms involved in the Schottky barrier formation, in which MIGS play a fundamental role. More importantly we emphasize the influence of the real interface beyond the complex band structure of bulk materials. 4.2 Metal-induced gap states and complex band structure In the presence of an interface between a metal and an insulator, those electronic states which are propagating states in the former but have energies inside the gap of the latter, do not vanish right at the interface between the two materials, but decay exponentially inside the insulator. This situation is, to some extent, analogous to the problem of a free electron traveling across a potential barrier of finite height. Quantum mechanics predicts that those electrons with a kinetic energy below the barrier still have a non-zero probability of tunneling through it, with this probability decaying exponentially with the barrier thickness. This dependence of the tunneling probability is due to the exponential decay of the wave function inside the potential barrier. Similarly, electrons in a metal encountering an interface with an insulator will decay exponentially when their energies lie inside the band gap of the second material, as shown schematically in Fig. 4.1(a). Of course, at the interface, the decaying states in the insulator side should match the propagating states from the metal, and properties associated to the MIGS would depend also on the matching conditions of the wave function. The exponentially decaying wave functions can be actually regarded as Bloch functions with an associated complex wave vector. We can directly take the 1-dimensional expression of a Bloch wave function as introduced in Sec. 2.6 ψ(z) = eikz un,k (z), (4.1) and introduce a complex wave vector k̂ = <(k̂) + i=(k̂) ψ(z) = ei<(k̂)z e−=(k̂)z un,k̂ (z). (4.2) It becomes inmediately evident that the wave function is now a regular Bloch function under an exponential envelope, as depicted in Fig. 4.1(a). Usually only real values of the wave vectors are discussed in textbooks, since infinite periodicity is assumed and, in that situation, wave functions growing exponentially in any direction would not be physically valid. However, localized wave functions with an exponential decay are indeed perfectly valid solutions of the Schrödinger equation in the presence of defects, surfaces or interfaces (in the remainder of this Chapter we will refer only to the case of 4.2. Metal-induced gap states and complex band structure 105 interfaces, but some of the discussions, and in particular those regarding the properties of the complex band structure, could be extended to other non-periodic systems). Our main interest in this Chapter is to compare the properties of MIGS obtained from the simulation of a realistic ferroelectric capacitor with those derived from the bulk complex band structure of the ferroelectric material. MIGS in these systems will decay in the direction perpendicular to the interface, which we choose as the z direction, but they still must be periodic in the (x, y) plane (due to periodic boundary conditions used in our calculations). As a consequence, this becomes a 1-dimensional problem in which we would search for eigenfunctions characterized by real wave vectors parallel to the interface, kk , and by a complex ones k⊥ = kz + iq perpendicular to it. Furthermore, the in-plane periodicity of the system makes the wave vector kk a good quantum number that should be preserved across the interface. Thus wave functions from the electrode side must match vanishing function on the insulator with the same kk . This is true in atomically coherent interfaces where the lack of disorder precludes the mixing of states with different kk . This was not a realistic assumption a few years ago, but current experimental techniques have achieved such control in the growth of thin films that, in practice, experimental samples can be well compared with our perfect defect-free systems and the hypothesis coherent and non dispersive interface appears reasonable. We shall see in the next Section that, even under the simplest theoretical model, allowing for complex values of the wave vector in the solution of the Schrödinger equation gives rise to vanishing states in the presence of a surface or an interface in an otherwise periodic system. 4.2.1 Complex band structure: a simple example Interesting insights on the properties of MIGS can already be achieved at the level of the nearly-free electron model [145]. This model for the electronic structure of a solid departs from the free-electron approach introducing, as a perturbation, a potential with the periodicity of the lattice. The effect of this perturbation is the mixing of wave functions at the k-points where different bands cross, causing the opening of energy gaps where solutions of the Schrödinger equation with real k-vectors are not allowed. We shall see, however, that wave functions with complex k-vectors are perfectly valid solutions for energies within the band gap. While these solutions are unphysical for an infinite system they can describe electronic states localized at surfaces or interfaces, Let us consider a 1-dimensional system as the one depicted in Fig. 4.1(b), consisting of two semi-infinite materials in close contact. On the left side we have a metallic region with a potential that we model as constant. In the insulator, on the right hand side in Fig. 4.1(b), the potential is a oscillating function with the periodicity of the lattice. Given its periodicity, the potential in the insulator can be expressed as a Fourier series. If, for the sake of simplicity, we restrict the Fourier expansion to the first term (besides the Γ term which is a constant) we get a potential in the insulator with the form 106 Chapter 4. Metal-induced gap states in ferroelectric capacitors ψ(z) (a) V (z) (b) 2Vg V0 Metal Insulator a z 0 Figure 4.1: (a) Typical wave function at a metal/insulator interface for an eigenstate with an energy in the insulator band gap, consisting in a propagating Bloch-like wave on the metallic side which decays exponentially on the insulator side. (b) Potential profile at the same interface. V (z) = V0 + Vg cos(gz), (4.3) where g = 2π/a is the shortest reciprocal lattice vector. Within the nearly-free electron model, the perturbative potential mixes eigenstates from different bands at the crossing k-points. Taking for instance the first crossing that takes place for at the Brillouin zone boundary (k = g/2), the eigenfunctions are a mixing of two plane waves, which are the eigenfunctions of the unperturbed system ψk (z) = Aeikz + Bei(k−g)z . (4.4) Inserting previous trial function into the time-independent Schrödinger equation d2 − 2 + V (z) ψ = Eψ, dz (4.5) leads to the following expression for the eigenvalues of the system (see Appendix C for the detailed derivation) E = κ2 + (g/2)2 + V0 ± κ2 g 2 + Vg2 1/2 , (4.6) 107 4.2. Metal-induced gap states and complex band structure a a Figure 4.2: Complex band structure at the Brillouin zone boundary within the nearlyfree electron model. where we have introduced a new variable κ = k − g/2, which is the deviation of the wave vector k from the Brillouin zone boundary. Notice that scanning over real values of κ (i.e. of k), one would necessarily find the real bands depicted as solid lines in Fig. 4.2, which display an energy gap at the Brillouin zone boundary where no states with real wave vectors are allowed. One could alternatively try imaginary values of κ (k̂ = π/a + iκ) in Eq. (4.6) and imaginary bands would be found connecting the real ones (dashed lines in Fig. 4.2). This very simple model is particularly interesting because it is useful to illustrate some of the fundamental properties of complex band structures: • Complex bands connect extrema of real bands through the imaginary part of the complex plane. This means that a high density of complex bands is usually found at high symmetry points of the Brillouin zone, where extrema of real bands are typically located. This will be discussed in more detail in Sec. 4.4 where complex the band structure of a realistic material is analyzed. • The imaginary part of the wave vector, =(k̂) = q is associated with a penetration length, δ = 1/2q, of the probability density associated to the evanescent state. The smaller the q (κ in this model), the larger the penetration length. If q vanishes, then the penetration length diverges and the corresponding wave function spread over the whole system, as a standard Bloch wave function. Therefore, and knowing that complex bands depart from extrema of real bands, the penetration length of the evanescent states grows (the imaginary part of the wave 108 Chapter 4. Metal-induced gap states in ferroelectric capacitors vector drops) as the energy of the state gets close to those extrema. This has some similarities with the case of a free electron tunneling through a potential barrier, where the tunnel probability increases as the electron kinetic energy approaches the height of the barrier. Conversely, if a complex band connects the top of the valence band and the bottom of the conduction band, the penetration of this band has its minimum around the middle of the gap (see Fig. 4.2). • The shape of a complex band is closely related with (i) the energy difference between the real bands it emerges from, and (ii) their curvature [152] (which in turn is related to the effective masses at the departing k-point). 4.2.2 Connection with Schottky barriers Since the works by Heine [102], properties of MIGS have been known to be closely linked with the formation of Schottky barriers in metal/insulator interfaces. The transfer of charge that takes place at the interface of an heterostructure and the resulting band alignment in connection with the bulk real and complex band structures can be better understood introducing the concept of charge neutrality level (CNL). Definition of the charge neutrality level Let us first take a step back and recall that, in bulk, only solutions of the one-electron Hamiltonian described in Sec. 2.4 with real k-vector are physically valid. Those solutions in a periodic system can be expressed as Bloch functions. As we have seen in Sec. 4.2.1, if the material is an insulator, its energy spectrum is characterized by the presence of a region of forbidden energies (gap) separating (at zero temperature and in non doped systems) occupied (valence band) and unoccupied states (conduction band). If we compute the density of states (DOS), using for instance Eq. (3.27), we obtain something resembling the sketch of Fig. 4.3(a). However, as demonstrated in Sec. 4.2.1, formally, the Schrödinger equation admits solutions with complex k-vectors, solutions that became physically meaningful in the presence of an interface. The eigenenergies of these evanescent states might lie within the energy gap of the insulator, as in the simplified model corresponding to Fig. 4.2. Now, if the local density of states is computed including the evanescent states a non vanishing DOS emerges in the gap [146], as shown schematically in Fig. 4.3(b). Normalization of the total DOS of the insulator material requires that the DOS carried by the MIGS must be compensated by a decrease of the DOS at the valence and conduction bands with respect to those in the unperturbed system [153, 154], as schematically depicted in Fig. 4.3(b). In order to discuss the character of the MIGS we should recall that, since the Hamiltonian of a system is an hermitian operator, its eigenfunctions constitute a complete basis of the Hilbert space. Then, an evanescent state can be expanded in terms of the eigenstates with real k-vector (physically valid solution of the Schrödinger equation of the periodic crystal). If we restrict ourselves to a 1-dimensional case, where evanescent 109 4.2. Metal-induced gap states and complex band structure Figure 4.3: (a) Schematics of the local density of states (LDOS) of a bulk, infinitely periodic system, showing the valence and conduction band. (b) Local density of states modified by the presence of a interface (shadowed area). MIGS are formed in the gap of the bulk material (darker region). The dashed lines in (b) represent the LDOS of the bulk material, far from the interface. The charge neutrality level is defined from the normalization condition of the DOS. states penetrate along the z direction perpendicular to the interface, this expansion can be expressed as ψ̂k̂ (z) = X n,k Cnkk̂ ψnk (r) = VB X n,k Cnkk̂ ψnk (z) + CB X Cnkk̂ ψnk (z) (4.7) n,k where VB and CB denote sums over eigenstates contained in the valence and conduction band respectively, and ψ̂(z) represents an evanescent state. From perturbation theory arguments it follows that the contribution of a given eigenstate with real k-vector, given by the coefficient Cnkk̂ , is proportional to 1/(E − Enk ) [155], where E is the eigenenergy of an evanescent state within the gap and En,k is an eigenvalue for a real k-vector. As a consequence, gap states take their weight primarily from those real bands that are nearest in energy [154] (allowing for wave function matching and symmetry rules). In the case of complex bands connecting states from the valence band to states within the conduction band, there must be a gradual transition across the gap of the character of 110 Chapter 4. Metal-induced gap states in ferroelectric capacitors the MIGS, from valence-like to conduction-like. Of course, the bulk material is neutral when all states below the top of the valence band (EV ) are filled, and those above the bottom of the conduction band (EC ) are empty. However, since evanescent states take their DOS from the “real” DOS (real in the sense that it comes real bands) filling up to EV would still leave empty part of the valence-like DOS that has been drawn into the gap. Conversely, filling up to EC would populate conduction-like evanescent states resulting in a local doping with electrons. Therefore there must exist an energy inside the gap region such that a filling of all states right up to it would result in a locally neutral system. The charge neutrality level is precisely this energy inside the gap of the insulator, marking the transition from mostly valence-like to mostly conduction-like (see Fig. 4.3). Accordingly, the charge neutrality level can be defined as the energy ECNL satisfying the following expression Z EV Z ECNL ρ̂(E) dE, ρ(E) dE = (4.8) −∞ −∞ where EV denotes the valence band maximum, and ρ̂(E) is the disturbed density of states at the interface, including both propagating and evanescent states. From Eq. (4.8) it immediately follows that Z EV −∞ ρ(E) dE − Z EV Z ECNL ρ̂(E) dE = −∞ ρ̂(E) dE. (4.9) EV The left hand side of Eq. (4.9) corresponds to the area between the dashed line and the shadowed area in Fig. 4.3(b) for energies below EV , while the right hand side is the integral of the MIGS from EV to ECNL . An equivalent condition can be defined in terms of the conduction band. Eq. (4.9) reflects the fact, mentioned above, that the DOS of the MIGS is taken from the valence and conduction band DOS of the ideal infinite material. Numerical estimation of the charge neutrality level Since ρ̂(E) emerges exclusively in the presence of an interface, the use of Eq. (4.8) to compute the charge neutrality level would require the calculation of a a very well converged DOS of the actual interface. Nevertheless, more practical ways to calculate the charge neutrality level in terms of the bulk spectrum of eigenstates with real k-vector can be defined. In particular, as a consequence of the 1/(E − Enk ) dependence of the coefficients in expansion of Eq. (4.7), the change of the character of the MIGS from dominantly valence-like to conduction-like can be linked to the change of sign of the Green function of the material [156, 154] The cell-averaged Green function is defined as G(R, E) = X n,k eikR . E − Enk (4.10) 4.2. Metal-induced gap states and complex band structure 111 Figure 4.4: Complex band structure of an alkane chain. The right panel shows the conventional band structure, for real k-vectors. The left panel shows β, the imaginary part of the complex solutions. The units of β are such that e−β is the reduction of the tunneling probability from one carbon to the next along the alkane chain. The red line indicates the dominant complex band, with the shortest β. Reprinted with permission from Ref. [152] (DOI: 10.1103/PhysRevB.65.245105). where R is a lattice vector, k is a Bloch wave vector in the first Brillouin zone, n is the band index, and Enk is the set of eigenvalues of the system. For a sufficiently large R, G(R, E) changes its sign at the charge neutrality level [154]. The MIGS in metal/insulator interfaces will decay in one particular direction, the direction perpendicular to the interface (which we choose as the z direction) while still obeying the in-plane periodicity. Given the 1-dimensionality of our problem lattice vectors R are chosen along the z axis. This transforms Eq. (4.10) into a integration over the in-plane Brillouin zone of a series of Green functions in one dimension [154] G(m, E) = X X eik⊥ mc . E − Enk (4.11) kk n,k⊥ This function however converges slowly with respect to the energy, typically requiring the sum over hundreds of bands to obtain a converged value of ECNL . Alternatively, it can be proved that the charge neutrality level of an individual complex band (the energy marking the transition along the band from mostly valence-like to mostly conduction-like) coincides with its branch point (the energy of infinite slope, dEk̂ /dk̂, of the band) [156]. For systems displaying one complex band clearly dominating MIGS formation in the band gap region (i.e a complex band with an imaginary part significantly smaller than the rest and that does not cross with any other), searching for the branch point might be a relatively simple method to calculate the charge neutrality 112 Chapter 4. Metal-induced gap states in ferroelectric capacitors level. This is the case of some molecular systems like alkane chains [152] which complex band structure is shown in Fig 4.4. Complex band structure of realistic materials are explained in detail in next section, but here we can already notice that for this system there is a complex band (in red in Fig 4.4), connecting the edges of valence and conduction bands, and with an imaginary part in the middle of the gap clearly smaller (larger penetration length) than the rest of the bands. For this particular case, calculating the branch point of this individual band is a simple way to estimate the charge neutrality level [152]. Unfortunately, in general many bands will contribute to the formation of the MIGS and this analysis is no longer straightforward. In those cases an “effective” branch point should be calculated. Since the branch point of an individual complex band corresponds to the maximum imaginary part of the k-vector, q, of the band (minimum penetration length), the “effective” branch point can be calculated as the energy of the maximally localized MIGS local density [155], or in other words, the energy of minimum penetration of the local density considering the overall contribution of all evanescent states. From the dependence with the energy of the coefficients Cnkk̂ in the expansion given by Eq. (4.7) it can be deduced that ρ̂(E) ∝ X n,k 1 , (E − En,k )2 (4.12) then, the maximum localization of MIGS local density is found at the energy satisfying the condition [155] X nk 1 = 0, (ECNL − Enk )3 (4.13) This approximation has proved to provide reliable estimations of ECNL for a great variety of materials [155] and the third power of the denominator results in a much faster convergence than Eq. 4.11 with respect to the energy. Determination of Schottky barriers As pointed out in Sec. 4.1 and discussed extensively in Chapter 3 the magnitudes governing many of the processes in metal/insulator junctions are the Schottky barriers (denoted by φn and φp for electrons and holes respectively). The magnitude of these energy barriers is, in turn, determined by the charge rearrangements that take place every time a junction between two different materials is formed. We devoted Chapter 3 to the development of rigorous procedures for the analysis of Schottky barriers from first-principles and the associated limitations. Here we aim to discuss the physical origin of Schottky barriers and the different effects involved, with especial attention to MIGS, the topic of this chapter, and the intrinsic role of interfaces. We have seen that when a metal/insulator junction is formed, propagating wave functions in the metal with energies in the insulator band gap, penetrate in the latter, decaying exponentially. The matching of the wave function requires that its symmetry 4.2. Metal-induced gap states and complex band structure 113 Figure 4.5: Schematic of the band alignment at a metal/insulator interface and the associated charge transfers. and the kk vector have to be preserved across the interface. At the insulator side of the interfaces, all evanescent states below the Fermi level became occupied, populating states above the charge neutrality level or leaving empty states below it. By definition of the charge neutrality level, the relative position of EF and ECNL determines the local net charge of the system and its contribution to the interface dipole. In Fig. 4.5 an schematic view of a band alignment in a metal/insulator junction is shown, indicating the position of the valence and conduction bands (EV and EC respectively), the Fermi level (EF ) and the charge neutrality level (ECNL ). The alignment of the band structures across the heterojunction takes place by means of charge rearrangement at the interface. The exchange of charge gives rise to a dipole which shifts the bands until equilibrium is achieved. In the end, the Schottky barrier, φn (for electrons, analogous expressions can be derived for holes), is obtained as φn = EC + ∆V − EF . (4.14) As mentioned above, as a consequence of the relative position of EF and ECNL , a net charge at the interface, σ, gives rise to a dipole σδ, where δ is the average penetration of the charge density due to evanescent states within the gap. The potential drop across the interface can be split into two contributions ∆V = ∆VMIGS + ∆V ∗ = −e σδ + ∆V ∗ , εε0 (4.15) 114 Chapter 4. Metal-induced gap states in ferroelectric capacitors where we have multiplied the electrostatic potential by the electronic charge to get the right sign of the energy bands shift. The first term in Eq. (4.15) is the potential step due to the electronic charge transfer to the MIGS. The term ∆V ∗ includes any other contribution, in particular the ionic and electronic relaxations that take place when the junction is formed and that are due to changes with respect to bulk in the chemical bonding at the interface. Notice that ε in the MIGS term takes into account the screening of the transferred charge provided by the lattice, so this expression implicitly contain also some contribution of the lattice relaxations to the formation of the interface dipole. On the other hand the calculation of the charge transfer σ involves a two-step process. First, the integral in space from the interface (z = 0) to a position deep in the insulator (z = ∞) must be performed for the LDOS of MIGS, ρ̂(z, E). This results in a surface density of MIGS, Ds (E), that then must be integrated between the charge neutrality level and the Fermi level σ = −e Z EF Z dE ECNL +∆V 0 ∞ dz ρ̂(z, E) = −e Z EF dE Ds (E). (4.16) ECNL +∆V Typically, in this kind of models of Schottky barrier formation, Ds (E) is assumed to be relatively homogeneous in energy within the gap so Ds (E) ∼ N , with N constant [157]. Within this approximation the charge extracted (injected) from (into) the gap states states below (above) the charge neutrality level is σ = −e (EF − ECNL − ∆V ) N. (4.17) Comparing Eq. (4.15) and (4.17) one notices that the equilibration of the Fermi energy across the interface involves a self-consistent process where the band alignment causes a transfer of charge that, in turn, shifts the bands altering the band alignment. The combination of Eq. (4.15) and (4.17) yields the potential step at equilibrium, ∆V . Finally, the Schottky barrier, φn , can be obtained from Eq.(4.14) as φn = S(ECNL − EF + ∆V ∗ ) + (EC − ECNL ), (4.18) −1 e2 N δ S = 1+ . εε0 (4.19) with S is a factor that provides a quantitative estimation of the screening provided by the MIGS and is discussed in more detail below. But before, let us try to make the connection with the expressions typically used in empirical models of Schottky barriers. In Eq. (4.18) and (4.19), all magnitudes except ∆V ∗ can be, in principle, extracted from bulk calculations of the materials constituting the interface (either from the real eigenstate spectrum or the complex band structure). However, empirical models usually rely on different magnitudes, namely the work function of the metal (Wf ) and the electron affinity of the insulator (χ), which constitute indirect measurements of the Fermi level and the conduction band bottom respectively (for the determination of the 4.2. Metal-induced gap states and complex band structure 115 Figure 4.6: Schematic of the band alignment at (a) a metal/vacuum and (b) an insulator/vacuum surfaces. 116 Chapter 4. Metal-induced gap states in ferroelectric capacitors Schottky barrier for holes φp , the ionization potential is used instead of the electron affinity). The work function is the energy required to extract an electron from the a metallic surface [see Fig. 4.6(a)] Wf = Evac + ∆VM − EF . (4.20) Analogously, the electron affinity of the insulator is the energy of the conduction band deep inside the material with respect to the vacuum level [see Fig. 4.6(b)] χ = Evac + ∆VI − EC . (4.21) As a consequence of these two magnitudes being surface measurements, two new potential steps (∆VM and ∆VI ) due to surface dipoles must be considered. Introducing this expression into Eq. 4.18, and referring also the charge neutrality level in the insulator vac = E to the vacuum level, ECNL vac + ∆VI − ECNL , we end up with vac vac φn = S(Wf − ECNL − ∆VI − ∆VM + ∆V ∗ ) + (ECNL − χ). (4.22) It is clear from Eq. (4.22) that the modeling of the formation of Schottky barriers from bulk properties of the interface constituent materials is far from straightforward. ∆VM and ∆VI are magnitudes intrinsic to the metal and insulator surfaces respectively, and might depend in a rather complex way on the surface orientation and termination, and on the strain state of the sample. The term −∆VI − ∆VM + ∆V ∗ , on the other hand, is necessarily intrinsic to the interface, accounting for the change in the chemical environment from having to separate surfaces to having a close contact between the insulator and the electrodes, and all the associated atomic and electronic relaxations. It might seem from equation (4.22) that the role of the MIGS in the Schottky barrier determination (which effect is collected by the factor S) should be, in most cases, overwhelmed by the interface-intrinsic terms. However, the usual approach is precisely the opposite, and model for Schottky barrier formation tend to neglect the effect of changes in the chemical bonding and model the formation of Schottky barriers relying purely on the contribution from the MIGS. This transforms Eq. (4.22) into vac vac φn = S(Wf − ECNL ) + (ECNL − χ). (4.23) Despite the crude approximation this expression is implicitly assuming, this simple model for the prediction of Schottky barriers from bulk properties has proved to be surprisingly predictive in the case of metal/semiconductor contacts [148, 158, 146]. In this context, the factor S is often referred as the “slope parameter” because when Schottky barriers of a semiconductor are plotted as a function of the work function of different metallic electrodes, a linear dependence is often found, with the slope being S. Extreme values of S within MIGS model describe two limit regimes. Either if the DOS of gap states is very low or their penetration is very small and the transfer of charge that takes place is negligible; or if there is indeed a transfer of charge but it is efficiently screened by the lattice, S → 1 and the Schottky barrier for electrons is simply φn = ΦM − χ. This is usually called the “Schottky limit”. If on the contrary, the DOS is large, any deviation 4.3. Computational details 117 of the Fermi level from the charge neutrality level results in a large transfer of charge that in turn, produces a dipole that pushes the Fermi level back towards ECNL . In this limit case, called “Bardeen limit”, S → 0 and φn = ECNL − χ, and the Fermi energy on the insulator side is effectively pinned at the charge neutrality level. Unfortunately it remains unclear whether S in Eq. (4.23) is really moslty due to formation of evanescent states, as it is in Eq. (4.22), or if interface-intrinsic effects could also account for a dependence of the Schottky barriers given by Eq. (4.23). With the improve in quality of interfaces and the first principles studies, larger deviations from the MIGS model are being observed, highlighting the importance bonding effects due to details of the chemical environment at the interface [159, 142]. Despite showing some signs of possible pathological band alignment in some of the studied interfaces (see Sec. 3.6.5 for a more detailed discussion on this point), Ref. [142] provide and insightful analysis of the role of interface-intrinsic effects, confronted with the parameters extracted from surface experimental measurements or obtained from bulk first-principles simulations. However, in this work the contribution from the MIGS was not explicitly treated. We will try in Sec. 4.5 to analyze how common assumptions in MIGS formation and their participation in the Schottky barrier hold when the real interface is explicitly described within a first principles simulation. 4.3 Computational details Two codes have been used in this work, Siesta [121, 160] for the simulation of the complete interfaces, and the Quantum-espresso [161, 162] package for the complex band structure calculations [163]. The use of two different codes is a delicate issue and thus keeping strict convergence criteria becomes critical in order to ensure the compatibility of all the simulations. In order to mimic the effect of the mechanical boundary conditions due to the strain imposed by the substrate, the in-plane lattice constant was fixed to the theoretical equilibrium lattice constant of bulk SrTiO3 (aSTO = 3.874 Å for Siesta and aSTO = 3.850 Å for Quantum-espresso). Quantum-ESPRESSO Calculations in Sec. 4.4 on bulk PbTiO3 were performed using different codes included in the Quantum-Espresso package. Relaxations were carried out with pwscf using a plane-wave cutoff of 40 Ry, a 12 × 12 × 12 Monkhorst-Pack [90, 113] mesh and ultrasoft pseudopotentials [164]. Froce and stress thresholds during the relaxations were 10−4 a.u. and 10−3 kbar respectively. Complex band structures were obtained with the code pwcond [163] included in the Quantum-Espresso package. 118 Chapter 4. Metal-induced gap states in ferroelectric capacitors SIESTA Computations in Sec. 4.5 on short-circuited SrRuO3 /PbTiO3 capacitors have been performed within a numerical atomic orbital method, as implemented in the Siesta code. Core electrons were replaced by fully-separable [122] norm-conserving pseudopotentials, generated following the recipe given by Troullier and Martins [123]. Further details on the pseudopotentials and basis sets can be found in Ref. [124]. A 12 × 12 × 2 Monkhorst-Pack [90, 113] mesh was used for the sampling of the reciprocal space of the capacitor, equivalent to a 12 × 12 × 2 Monkhorst-Pack mesh in the bulk primitive cell. A Fermi-Dirac distribution was chosen for the occupation of the one-particle Kohn-Sham electronic eigenstates, with a smearing temperature of 8 meV (100 K). The electronic density, Hartree, and exchange-correlation potentials, as well as the corresponding matrix elements between the basis orbitals, are computed in a uniform real space grid, with an equivalent plane-wave cutoff of 1200 Ry in the representation of the charge density. To simulate the capacitors in a non polar configuration, we impose a mirror symmetry plane at the central TiO2 layer, and relax the out-of-plane stress and the internal forces of the resulting centrosymmetric tetragonal phases until they are smaller than 10−4 eV/Å3 (= 1.602 · 10−3 kbar = 1.602 · 10−4 GPa) and 0.01 eV/Å(= 1.945 · 10−4 a.u.), respectively. 4.3.1 Compatibility tests The tests we have performed have shown that the parameters above provide converged values of the atomic (Table 4.1) and band structures (Fig.4.7) of the bulk material. Given the sensitivity of complex bands to the size of the gap and the curvature of real bands at the connecting k-points [165], a good agreement between the band structures obtained with both codes is required to obtain comparable results. Fig. 4.7 shows that the band structures obtained with both codes are essentially indistinguishable in shape, although the pwscf calculations display a slightly larger gap. This must be taken into account since larger gap is going to translate in slightly larger values of the imaginary part of complex wave vectors. It is also important to note that the bulk paraelectric phase we are discussing here is not the cubic phase, but a tetragonal centrosymetric P 4/mmm phase. We compare complex band structure calculations on bulk PbTiO3 with properties of MIGS in a capacitor where the out-of-plane cell vector is allowed to relax. As required by the strong sensitivity of complex bands on the real band structure, bulk calculations must be performed under the same symmetry constrains applied to the PbTiO3 layer in the capacitor. 4.4 Complex band structure of bulk PbTiO3 We have seen in Sec. 4.2 how imaginary bands appear naturally even at the level of the nearly-free electron model. Such a simplistic model is useful to illustrate the origin of 119 4.4. Complex band structure of bulk PbTiO3 Table 4.1: Lattice vectors of PbTiO3 and SrTiO3 with Siesta and pwscf. For SrTiO3 u = a while for PbTiO3 u = c calculated imposing an in-plane lattice constant equal to that of SrTiO3 (aPTO = aSTO ). Experimentally, at room temperature, in-plane lattice k constant of bulk PbTiO3 is virtually the same than aSTO , this justifies the comparison with the experimental value of c/a in bulk PbTiO3 . Values in brackets are the tetragonality c/a. cubic non polar polar upwscf (Å) 3.850 3.901 (1.013) 4.012 (1.042) 5 5 4 4 3 3 2 2 1 1.558 eV Eg = 1.462 eV 2.660 eV 0 Energy (eV) Energy (eV) SrTiO3 PbTiO3 usiesta (Å) 3.874 3.907 (1.009) 4.030 (1.040) -1 1 1.412 eV 2.544 eV Eg = 1.354 eV 0 -1 -2 -2 -3 -3 -4 -4 -5 uExp (Å) 3.905 4.156 (1.064) Γ Z R A Γ X -5 Γ Z R A Γ X Figure 4.7: Band structures of bulk non-polar PbTiO3 obtained with pwscf (left) and Siesta (right). The symmetry of the unit cell is P4/mmm, since the in-plane lattice constant was fixed to the theoretical one of SrTiO3 and the out-of plane lattice constant was allowed to relax, while atoms were kept in the centrosymmetric positions. A direct gap is found at X. the evanescent states characterized by the complex wave vectors, but as for the usual band structure calculation, real systems are much more complicated. The idea behind a complex band structure calculation within DFT though, can be perfectly extrapolated from the example detailed in previous Section. Usually, conventional band structure calculations involve solving the energy eigenvalue problem scanning over real values of k-vectors along high symmetry directions in k-space. This procedure produces the well known band structure E(k). This method is convenient because very often interesting features of the real band structure are located at high symmetry k-points, and a scan along high symmetry directions usually provide the information we need for the interpretation of multiple physical phenomena. Similarly one could also perform a scan over complex values of the wave vectors 120 Chapter 4. Metal-induced gap states in ferroelectric capacitors 2 Energy (eV) 1 0 - -1 -2 1 0.5 q (2π/c) 0 0.5 kz (2π/c) 0.5 q (2π/c) 1 Figure 4.8: Complex band structure of centrosymmetric P4/mmm PbTiO3 at kk = Γ̄. Central panel correspond to <(k⊥ ) and side panels to =(k⊥ ). The dashed lines delimit the band gap. Color code is described in the main body of Sec. 4.4. to obtain the complex band structure. Nevertheless, given the kind of information provided by imaginary wave vectors (evanescent states, tunneling, etc.), when we perform a complex band structure calculation we are usually interested in small energy ranges (the band gap) and large areas of the Brillouin zone, so previous approach turns out to be quite inefficient. An alternative approach is typically used instead: the scan is performed over the energies and the spectrum of k-vectors producing real values of the energy is obtained. Notice, looking at Fig. 4.2 for instance, that under this approach imaginary bands emerge in a completely transparent way. As pointed out in Sec. 4.2.1 imaginary bands always connect extrema of the real bands. These extrema are most of the times located at the high symmetry points in the Brillouin zone, which means that at those special k-points there will always be a great density of imaginary bands. Besides, at the energies of interest, i.e. the energy gap, the band with the shortest q (largest penetration length) is typically one that connects the edges of the valence and conduction bands. The analysis of the real band structure depicted in Fig. 4.7 reveals that, in the non polar P4/mmmm phase, PbTiO3 posses a direct gap located at X, and a relatively narrow gap, slightly larger than the direct one at Z. Therefore we can presume that in non-polar PbTiO3 , complex bands with the shortest imaginary wave vector q are going to depart from the those high symmetry points of the Brillouin zone. Such complex wave vectors will have the form (π/a, 0, iq) and (0, 0, π/a + iq) respectively, which correspond to complex bands at kk = X̄ and Γ̄ in the 2-dimensional Brillouin zone parallel to the interface. Complex band structures of bulk non polar PbTiO3 was obtained performing a sampling of 48 × 48 k-points in the 2-dimensional Brillouin zone. Since important features 121 4.4. Complex band structure of bulk PbTiO3 2 Energy (eV) 1 0 -1 -2 1 0.5 q (2π/c) 0 0.5 kz (2π/c) 0.5 q (2π/c) 1 Figure 4.9: Complex band structure of centrosymmetric P4/mmm PbTiO3 at kk = X̄. Central panel correspond to <(k⊥ ) and side panels to =(k⊥ ). The dashed lines delimit the band gap. Color code is the same as in Fig. 4.8 and is described in the main body of Sec. 4.4. of the complex band structure take place at high symmetry k-points, a centered k-point mesh was used to include the special points. Complex band structure at Γ̄ (Γ → Z path in the 3-dimensional Brillouin zone) and X̄ (X → R path in the 3-dimensional Brillouin zone) are shown in Fig. 4.8 and 4.9 respectively. Some of the features described in Sec. 4.2.1 for the simple model are also observed in the DFT complex band structure of PbTiO3 . Imaginary bands always connect extrema of the real bands (and also of complex bands), usually located at the high symmetry points in the Brillouin zone. Taking this into account, and following the notation established by C.-Y Chang [165], complex bands at every kk can be classified into four different categories: (i) Real bands, with q = 0 (black lines in the central panel of Fig. 4.8 and 4.9). (ii) Imaginary bands with q 6= 0 and kz = 0 (black lines in the left panel), that we will label as “of the first kind” after the notation introduced by C.-Y Chang [165] . (iii) Imaginary bands of the second kind, with q 6= 0 and kz = π/a (black lines in the right panel). (iv) Complex bands with q 6= 0 and kz 6= 0 or π/a (real part of these bands is plotted as a red line in the central panel and imaginary part as a red line in the left or right panel depending if they connect imaginary bands of the first or second kind respectively). Also complex bands connecting imaginary bands of different kind can exist but we don’t find any at these k-points and energy ranges. 122 Chapter 4. Metal-induced gap states in ferroelectric capacitors Figure 4.10: Minimum value of q (corresponding to maximum penetration lengths) for values of kk over a quadrant of the 2D Brillouin zone. We observe in Fig. 4.8 and 4.9 that at the kk defining the gap of the material (delimited with dashed lines in Fig. 4.8 and 4.9) , and for energies around the middle of the gap, the bands with the shortest q (largest penetration length) take values from 0.10 to 0.15 in units of (2π/c). Bands around these two high symmetry k-points in the 2-D Brillouin zone are expected to dominate tunnel conductivity phenomena [166]. However these k-points represent a very small fraction of the area of the 2-D Brillouin zone. In Fig. 4.10 we plot the surface of minimal q over one whole quadrant of the 2-D Brillouin zone for an energy in the middle of the gap. We can see that bands with the lowest decay rates are located at Γ̄ (corresponding to the branch departing from the top of the valence band at kz = π/c in Fig. 4.8, i.e. the Z point in the 3-D Brillouin zone). ¯ direction, from Γ̄ to X̄. There is also an important contribution coming from kk in the ∆ However, besides the contribution from high symmetry points and paths, there is also a ¯ path with still small values of large, relatively flat area out of the axes defined by the ∆ q (q ∼ 0.2, red plateau in Fig. 4.10). These states could also play an important role, not only in Schottky barrier formation, but also in tunneling phenomena [166], depending on the shape of the Fermi surface of the metal [129]. The complex band structures at Γ̄ and X̄ plotted in Fig, 4.8 and 4.9 respectively, might not be representative of the whole complex band structure of the system, since they represent such a small fraction of the total 2-D Brillouin zone. The integrated contribution from the complete 2-D Brillouin zone to the complex band structure is analyzed in Fig. 4.11(a), where we plot the the density of states, Nq (E), due to all kk , 4.4. Complex band structure of bulk PbTiO3 123 Figure 4.11: (a) Density of states with respect to the the energy and the imaginary wave vector q. This histogram in two variables is generated considering the complex bands at every kk over the 2-D Brillouin zone. Then, the density of complex bands [the density of q(E) points] is plotted as a gray scale, where darker regions represent a larger density of bands. The zero of energies corresponds to the top of the valence band. (b) A slice of the density of states plotted in (a) for and energy E = 0.7 eV above the top of the valence band [dashed line in (a)]. 124 Nqdecay (a.u.) Chapter 4. Metal-induced gap states in ferroelectric capacitors m=4 m=8 m=16 0 0.05 0.1 m=32 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5 q (2π/c) Figure 4.12: q-resolved density of states weigthed with the decay rate e−2qm , measuring the tunnel probability of states with imaginary wave vector q across a barrier with a thickness of m unit cells. with respect to the energy E and the imaginary part of the wave vector q. Fig. 4.11(a) is actually a 2-D histogram in which the gray scale indicate the number of complex bands contributing to each q(E) point. Darker regions indicate a larger density of complex bands. A careful analysis of this plot reveals that those bands at Γ̄ with q ∼ 0.1 (2π/c) (see Fig. 4.8) are completely inappreciable here, since only one kk of the 2-D Brillouin zone is contributing. On the other hand, the total complex band structure is clearly dominated by bands at q ∼ 0.2 and q ∼ 0.3 in units of (2π/c). The relative weight of different values of q in the density of states can be better quantified plotting a slice of the Nq (E) of Fig. 4.11(a). In Fig. 4.11(b) we plot the profile of Nq (E) for and energy in the middle of the gap [E = 0.7 eV above the top of the valence band, dashed line in Fig. 4.11(b)]. Here we see that the weight of the bands at q ∼ 0.2(2π/c) and q ∼ 0.3(2π/c) is about 100 times larger than the contribution from Γ̄ [showing up in Fig. 4.11(b) as a weak band at q ∼ 0.1(2π/c)] In order to get a qualitative hint about the relative importance of states with larger q in the tunneling phenomena we have plotted in Fig. 4.12 the density of states relative to q, Nq , weighted with the tunnel probability e−2qm 1 , for various barrier thicknesses m. This quantity represent the relative contribution to the tunneling of states with different values of q [166]. We observe that the large band of Nq around 0.2 in units of (2π/c) decreases rapidly its weight as the barrier thickness increases. Nevertheless, for thicknesses up to 16 unit cells the contribution to the tunneling of these states are still as important as that of the most penetrating band at Γ̄. The contribution from Γ̄ becomes dominant for m ∼ 32. This result highlights the necessity of considering higher 1 The decay rate of an evanescent wave function is given by q. The decay of the probability density (or equivalently, the charge density) is given by the square of the wave function, explaining the factor 2 in the exponential. 125 4.4. Complex band structure of bulk PbTiO3 order imaginary bands and non high-symmetry points in the 2-D Brillouin zone in the analysis of tunneling phenomena. The polarization of PbTiO3 modifies its band structure, and in particular the band gap is increased. Even though the indirect gap (from X to Γ) changes little within LDA (about 5%), there is very significant opening of the direct gap at the X high-symmetry point. Most of the complex bands only connect real bands departing at the same kpoint, thus the development of a polarization in the ferroelectric layer should cause an increase of the minimal imaginary wave vector at this particular point of the Brillouin zone, reducing the tunneling probability across the barrier. If analogous calculations of the complex band structure were to be done for the ferroelectric configuration of the capacitor, they should be performed at the same electric displacement field as the PbTiO3 layer in the capacitor. The analysis of the complex band structure also provides relevant information about the Schottky barrier formation, for instance, allowing the estimation of the effective penetration of MIGS, δ in Eq. (4.19). This quantity represents the center of mass of the charge contained in the MIGS. This argumentation comes with a caveat: not all complex bands (as calculated for the bulk material) contribute to the formation of MIGS at the interface; matching arguments (including symmetry of the bands and preservation of the kk across the interface) ultimately determine their distribution. Taking this into account requires a realistic simulation of the interface, as will be done in Sec. 4.5. Keeping this consideration aside, we can still obtain a crude estimation of δ from the complex band structure. If we choose the interface to be located at z = 0, the center of mass of the probability density of one individual exponentially-decaying state is located as z = 1/2q. Then the individual decay length of each band should be weighted by the integral of the corresponding exponential decay, 1/2q as well (here we are again disregarding any prefactor that might arise from the matching of the wave function at the interface). Under these approximation, the collective penetration of MIGS can be estimated from the complex band structure as 1 X δ(E) = ni ,kk 1 2qni kk (E) 2qni kk (E) X ni ,kk 1 2qni kk (E) X ni ,kk = X ni ,kk 1 4qn2 i kk (E) 1 , (4.24) 2qni kk (E) where ni denotes the imaginary band index. In practice sums in Eq. (4.24) are found to be well converged for q < 3, yielding a value of δ = 0.20 unit cells (or equivalently 1.47 Bohrs) for an energy in the middle of the gap. This quantity will be compared in next section with the effective decay of MIGS obtained from the simulation of a whole metal/PbTiO3 interface. Also important for the study of Schottky barriers is the charge neutrality level, which can be obtained from the spectrum eigenstates with real k-vector of bulk PbTiO3 , as explained in Sec. 4.2.2. The eigenstate spectrum was obtained performing a non-selfconsistent calculation with a centered 72 × 72 × 72 k-point sampling. Using Eq. (4.10) 126 Chapter 4. Metal-induced gap states in ferroelectric capacitors convergence of the charge neutrality was not achieved using up to 80 bands. Eq. (4.11) on the other hand, converged with just about 20 bands to a value of ECNL = 0.66 eV above the top of the valence band, close to the mid-gap energy, located at 0.69 eV with respect to the VBM. As a consequence of the well known band-gap underestimation by LDA, if this value were to be compared with experimental measurements of Schottky barriers it should be scaled with the experimental band gap of PbTiO3 of 3.40 eV [126], yielding a value of 1.66 eV above the top of the valence band. 4.5 MIGS in ab initio simulations of ferroelectric capacitors A more rigorous approach for the study of the properties of MIGS in the metal/ferroelectric interface is the simulation of an actual capacitor from first principles. Results from the full simulation not only would account for properties of MIGS derived from the complex band structure of the bulk ferroelectric but also for any intrinsic interfacial property that could affect the gap states. We have simulated a SrRuO3 /PbTiO3 capacitor as model system. The ferroelectric film is 8.5 unit cells thick, terminated in a TiO2 atomic layer. The metal electrode is 5.5 unit cells thick, terminated in SrO. Test simulations with electrodes up to 9.5 unit cell thick were performed to confirm that interfacial effects are perfectly screened within the metal but results showed no difference with respect to simulations with 5.5 unit-cell-thick electrodes so only results on the latter are reported. The analysis of MIGS in full capacitor simulations requires to work with some sort of energy-resolved probability density. For this, the LDOS defined as in Eq. (3.26) could be used. However, strong oscillations of this function due to the underlying atomic structure could difficult the analysis. Alternatively, the nanosmoothed version of this function might be used, but some interfacial properties, like precisely the decay length of the MIGS charge in the band gap, are sensitive to the specific convolution function used for the nanosmoothing procedure. A reasonable choice is to work with the layer-by-layer (z-resolved) PDOS (E-resolved). In this case the bias of the method lies in the choice of the basis of atomic orbitals. However, a sufficiently converged basis should minimize its effect and atoms of the same species at different sites are equally described, so the z dependence might be considered as less biased than with previous methods. In Fig. 4.13 we plot the layer-by-layer PDOS of the simulated capacitor. The energy distribution of the charge density (the PDOS in this particular case, the DOS in general) converges much slower with the k-point sampling than its spatial distribution, for this reason the PDOS was calculated performing an extra non-self consistent calculation with a finer k-point grid of 54 × 54 × 9. Only half of the atomic layers of the ferroelectric are plotted in Fig. 4.13 due to the mirror symmetry plane present in the non-polar configuration. The fast decay of the MIGS can be clearly observed, being negligible for atomic layer further than 2 unit cells from the interface. We can obtain a measure of the spatial distribution of the probability density at a 4.5. MIGS in ab initio simulations of ferroelectric capacitors 127 Figure 4.13: Layer-by-layer projected density of states of the ferroelectric inside the capacitor. The plot at the bottom corresponds to the atomic layer at the interface with the electrode, while the plot at the top is the PDOS corresponding to the layer in the middle of the ferroelectric film. The dashed lines delimit one of the energy windows used to perform the integrations in Eq. (4.25). 128 Chapter 4. Metal-induced gap states in ferroelectric capacitors given energy integrating the PDOS in small energy windows centered at different energies inside the band gap Z QPDOS (Ei , zj ) = Ei + ∆E 2 Ei − ∆E 2 PDOSj (E)dE, (4.25) where subindex j denotes the atomic layer. The decay of this quantity into the ferroelectric provide a direct way to obtain the effective decay length δ(E) of the gap evanescent states. Alternatively we can talk about an effective imaginary wave vector qeff (E), describing the effective decay of the wave functions. Since δ(E) is obtained from the decay of PDOS, connected with the probability density, it is related with qeff (E) (the decay rate of the wave function) as δ(E) = 1/2qeff (E). (4.26) To obtain the dependence of the decay length, or conversely the effective imaginary wave vector qeff (E), with the energy inside the gap, we have integrated the PDOS using Eq. ∆E (4.25) inside energy windows [Ei − ∆E 2 , Ei + 2 ] with ∆E = 0.02 eV (one of this windows is indicated in Fig. 4.13 as the energy range between the dashed lines). An example of QPDOS (Ei , zj ) is plotted as circles in Fig. 4.14 for an energy window in the middle of the band gap. Then the effective value of the imaginary wave vector is obtained fitting those points to a function QPDOS (E, z) ' cosh(2qeff (E)z), (4.27) which is plotted in Fig. 4.14 as a black dashed line. A hyperbolic cosine was used to account for the presence of two interfaces, although the analysis in Fig. 4.13 and 4.14 shows that there is very little overlap of MIGS coming from opposite interfaces. Repeating this procedure for energy windows covering the whole energy gap of the ferroelectric we obtain the energy dependence of the effective imaginary wave vector, qeff (E). This effective value of the imaginary wave vector is plotted as a solid black line in Fig. 4.15 as a function of the energy. It is legit to assume that this qeff (E) reflects the collective contribution of all complex bands in the gap of PbTiO3 . In the background of Fig. 4.15 we plot a zoomed region of the density of complex bands Nq (E) with respect to the energy and the imaginary wave vector for bulk PbTiO3 , as previously plotted in Fig. 4.11(a) and discussed in Sec. 4.4. In systems with one complex band with a imaginary part notably smaller than the rest (see Fig. 4.4), effective decay rates obtained from the LDOS of the actual interface has been found to overlap very accurately with that (dominant) complex band [152]. In the present case there are clearly two groups of bands clustered at q ∼ 0.2 and ∼ 0.3 in units of (2π/c) that dominate the complex band structure of bulk PbTiO3 . This is reflected in the qeff obtained from the PDOS of the actual interface, which oscillates between those two values throughout the gap. The contribution of the Γ̄ point to smaller values of q (invisible in Fig. 4.15 due to its low weight) is overwhelmed by the much larger area of the 2-D Brillouin zone contributing to larger values of q. As a final remark regarding Fig. 4.15, we should mention that the 4.5. MIGS in ab initio simulations of ferroelectric capacitors 129 3.5 3 log10(QPDOS) (a.u.) 2.5 2 1.5 1 0.5 0 −0.5 TiO2 PbO TiO PbO TiO2 PbO TiO PbO TiO PbO TiO PbO TiO PbO TiO PbO TiO2 2 2 2 2 2 2 Figure 4.14: Charge (in arbitrary units) obtained integrating the layer-by-layer PDOS in an energy window in the middle of the band gap (black circles). The decay of the charge inside the ferroelectric material is fitted to a curve following Eq. (4.27) centered at the mirror symmetry plane located in the middle of the capacitor (red curve). larger gap obtained within pwscf (see Fig, 4.7) is responsible for the imaginary bands dropping to q → 0 at about 0.1 eV above the bottom of the conduction band of the capacitors (simulated with Siesta). Another quantity which is relevant to the MIGS and in connection with the Schottky barrier formation is the surface density of metal-induced gap states Ds (E). This is can be computed as Z 1 ∞ Ds (E) = ρ(r, E)dz, (4.28) A 0 where A is the interface area [(3.874 Å)2 in our case], ρ(r, E) is the LDOS as defined in Eq. (3.26), and the integral over z is to be performed from the interface to deep into the ferroelectric layer [in Eq. (4.28) we are assuming a semi-infinite insulator]. Performing the integral of Eq. (4.28) is equivalent to sum the PDOS plotted in Fig. 4.13 over all atomic layers in the ferroelectric. The resulting surface density of states is plotted in Fig. 4.16. With the knowledge of the effective decay rate of gap states and their density of states, shown in Fig. 4.15 and Fig. 4.16 respectively, an estimation of the slope parameter can be obtained. The definition of the slope parameter S in Sec. 4.2.2 assumes a constant value of both the penetration length and the surface density of states within the gap. In particular, the integral in Eq. (4.16) is approximated by an average density of states, N , times the energy difference between the Fermi level and the charge neutrality level, 130 Chapter 4. Metal-induced gap states in ferroelectric capacitors Figure 4.15: Effective imaginary wave vector qeff obtained fitting the decay of the PDOS inside the ferroelectric material of the capacitor (black line) and imaginary wave vectors at high symmetry points of the 2-dimensional Brillouin zone. In the background we plotted the density of complex bands of bulk PbTiO3 integrated over the whole 2-D Brillouin, as was previously plotted in Fig. 4.11(a) and discussed in Sec. 4.4. The energy of the bulk complex band structure has been shifted to align its valence band maximum with that of the PbTiO3 layer in the capacitor. assuming a slow variation of Ds (E). Curves in Fig. 4.15 and Fig. 4.16, however, display a rather complex dependence of both the penetration length and the surface density of states with the energy in the gap. A relatively strong pinning of the Fermi level would make the estimation of the slope parameter very sensitive to the particular values of the density of states and penetration length of the MIGS around (and close to) the charge neutrality level. If, on the contrary, the Fermi level is significantly shifted from the charge neutrality level, the details of the curves in Fig. 4.15 and Fig. 4.16 are averaged out and the use of constant values of the effective decay hδi and the surface density of states inside the gap hDs i [N in Eq. (4.19)] is justified. Here we find a large shift of the Fermi level with respect to the charge neutrality energy (EF ' ECNL + 0.31 eV, using ECNL obtained in Sec. 4.4), supporting the use of averaged values. The effective decay hδi and the surface density of states inside the gap hDs i, as obtained from the simulation of the actual capacitor, are gathered in Tab. 4.2, together with an approximated value of the dielectric constant of PbTiO3 . These magnitudes 131 4.5. MIGS in ab initio simulations of ferroelectric capacitors 0.20 Ds (states/eV) 0.15 0.10 0.05 0.00 -2 -1 -1.5 0 -0.5 0.5 1 Energy (eV) Figure 4.16: Surface density of metal-induced gaps states in the PbTiO3 /SrRuO3 capacitor. Table 4.2: Parameters for the calculation of the slope parameter. Averaged values of the penetration length (in atomic units) and surface density of MIGS (in states/eV), relative permittivity of PbTiO3 and estimated value of the slope parameter. hδi 2.65 hDs i 0.0512 ε 100 S 0.99 yield an estimated value of S = 0.99, very close indeed to the Schottky limit (weak pinning). The value for the slope parameter we obtain from the MIGS study in the whole capacitor is much larger than that obtained by Robertson et. al. by means of a tight binding model fitted to experimental photoemission and optical data [157]. These authors report a value of S = 0.31 for PbTiO3 , far from the Schottky limit we found. Our large value of the slope parameter is mainly a consequence of the relatively small density of states in the gap. Unfortunately this method for the calculation of the slope parameter S has the limitation of the intrinsic arbitrariness of the position of the interface. Calculation of the surface density of states of the MIGS relies on the integration of the DOS of gap states from the interface to a position deep in the insulator layer, as in Eq. (4.28). Given the exponential decay of MIGS, small changes in the chosen position of the interface can modify severely the estimated value of the surface density of states. PDOS provides an intuitive criterion for the calculation of the surface density of states, 132 Chapter 4. Metal-induced gap states in ferroelectric capacitors performing the integration over the DOS projected over all the atoms in the insulator layer. Nevertheless the arbitrariness persist, since interfacial atomic layers (SrO on the electrode side and TiO2 on the ferroelectric) might be regarded as partially metallic or insulating. However, the dependence of S obtained from Eq. (4.19) on the density of states is very weak: increasing the value of hDs i by hand in one order of magnitude only reduces S to about 0.92. This suggest that, even if the result of S ∼ 1 is probably unrealistic due, mainly, to limitations in the determination of N , the formation of the interface dipole (and as a result of the Schottky barriers) in this system is probably dominated by interface-intrinsic atomic relaxations and not by the contribution of the MIGS. 4.6 Discussion and perspectives The research reported in this Chapter is still a work in progress. Here we have made an effort to compile many different aspects related to the MIGS that arise often in the literature, and we have perform a detailed characterization for the case of a ferroelectric capacitor. These properties are often discussed in different contexts (tunneling, Schottky barriers, screening, etc) but are rarely connected, making difficult to have a broad picture of the MIGS properties and the various phenomena they are involved in. Here, we have seen that basic characteristics of MIGS can be traced back to properties of the complex band structure in the bulk insulator material. We have seen that even disregarding the matching of the wave function at the interface, the penetration of the evanescent states clearly resemble the complex bands. Less has been discussed about the DOS of MIGS, for this the matching of the wave function is expected to play a more important role than in the case of the penetration length. How this affects derived properties should be investigated in more detail. At the same time, our study highlights the importance of a careful analysis of the complex band structure: common approximations, like considering only bands at high symmetry k-point in the 2D-Brillouin zone must be performed with great care, specially in perovskite oxides where many kk , and many bands at each kk , might contribute similarly. This consideration directly affects the energetic and spatial distribution of the evanescent states, which is, of course, of great importance for the analysis of the tunneling conductivity of the junctions or the role of the MIGS on the interface dipole. We have seen that the MIGS model for the analysis of Schottky barriers only reflects part of the process that takes place during charge rearrangement at an interface. Previous works have already highlighted the importance of atomic relaxations and chemical bonding in the formation of the interfacial dipole [159, 142]. Separate different contributions to this problem is tremendously complicated. The best effort so far has been, to our knowledge, the work by Mrovec et. al. [142]. This work demonstrates the importance of the interface details (termination of the surfaces, atomic relaxation or type of electrode) in the Schottky barrier formation, separating the atomic relaxations with the electronic transfer of charge. However, we have seen in the derivation and breakdown of Eq. (4.18) that both atomic an electronic rearrangements are a mix of contributions intrinsic to the 4.6. Discussion and perspectives 133 constituting materials and to the interface. Here we are trying to decouple, at least, the part due to the MIGS by correlating their properties to the bulk complex band structure; pointing out, at the same time, the extent of validity of the approximations. For instance, interface-intrinsic effects like the matching of the wave function or the changes in the chemical environment with respect to bulk or the surface, is likely to modify significantly, not only the DOS of MIGS, but also the charge neutrality level. Charge neutrality level has always be considered a bulk property of the insulator, however it is a property derived from evanescent states that only emerge in the presence of a surface or an interface. If we admit that the particular details of the interface are playing a role in the energetic and spatial distribution of the evanescent states, it follows that the charge neutrality level itself can vary from one particular interface to another. Nevertheless, MIGS are not relevant only in the context of Schottky barriers, even beyond the discussion about its relative importance in the formation of the interface dipole, it is important to ascertain to what extent the MIGS properties themselves are properties of the bulk material or of the interface. Some more insight in this direction could be gained improving the connection between the complex band structure and the MIGS distribution in the actual interface. Considerations about the matching conditions at the interface are very likely to be important. For this, introducing new ingredients in the model, like the k-resolved DOS of the electrodes, is desirable. A definite test about the intrinsic character of MIGS (bulk-like or interface-like) could be carried out doing simulations on different metal/insulator for the same insulating material and then, performing the same analysis as in Sec. 4.5. The problem here relies on the band alignment issues discussed in Chapter 3, since very few metallic electrodes provide non pathological interfaces. This is one study that would certainly benefit from the use of improved functionals, like the one developed by D. Bilc and coworkers [78]. This move would not only improve the comparison between first-principles simulations and experiments thanks to the better description of the electronic structure, but it would also increase the number of possible electrodes to be used in the investigation. This whole thesis is devoted to the study of ferroelectric thin films. In this Chapter, although we have focused on a paraelectric capacitor and most of the discussion is quite general, it is natural to extend the study to the polar case. We have seen in Chapter 3 the dramatic effects the polarization of a capacitor has on its band alignment. The band structure term is altered, displaying a reduction of the band gap that should affect the penetration of the MIGS and, by extension, interface dipole and tunneling effects. At the same time, the bands are tilted as a consequence of the depolarizing field arising in the ferroelectric film. The effect of the electric field on the MIGS properties will be explored performing analyses analogous to those of Sec. 4.5 on ferroelectric capacitors in a polar configuration. The results of this research would be particularly relevant for the study of ferroelectric tunnel junctions and electroresistance. Chapter 5 Ferromagnetic-like closure domains in ferroelectric capacitors 5.1 Introduction Previous Chapters focused on interfacial properties in monodomain capacitors, where polarization distribution – whether when it was zero (as in non-polar configurations where polarization was not allowed to develop), or not (as in polar configurations) – is homogeneous throughout the ferroelectric layer. Monodomain phases of ferroelectric thin films where the polarization points perpendicular to the interfaces/surfaces are known to be destabilized by the depolarizing field [53], as discussed in Sec. 1.3.2. Previous first principles local density calculations on realistic short-circuited ferroelectric capacitors suggested a critical thickness for monodomain phase destabilization that ranged between m = 2 and m = 6 layers [53, 167, 128] of ferroelectric, depending on the perovskite, the electrode, and the termination at the interface. In all these approaches the electrode was the only source of screening, providing free charges that accumulate at the interface on the metallic side and even decay exponentially into the first few layers of the ferroelectric (the MIGS discussed in previous Chapter), or sharing the ionic displacements responsible for the polarization in the ferroelectric [168]. In any case, the mechanism is ineffective below this critical thickness where the paraelectric phase was stabilized. It is expected thus, the existence of a transition thickness below which the breaking up into polarization domains is preferred over the monotonic reduction of the polarization in order to avoid the increase of electrostatic energy. Exhaustive experimental studies on the critical size of ferroelectricity have recently observed this transition [169, 170, 171], although it has been found not to happen for some combinations of metal and ferroelectric material [169]. Thus the question of whether the transition, as the thickness of the ferroelectric film decreases, takes place as a gradual reduction of the polarization in a monodomain phase until paraelectric phase is reached below the critical thickness, or if a breaking up into domains takes place remaines unclear. 135 136 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors Recently, Landau theory models developed by Bratkovsky and Levanyuk [172, 173] suggest that polydomain phases always exist in ferroelectric thin films. These authors even claim that polydomain phases are the most stable phase for any thickness with monodomain phases being just metastable configurations above the critical thickness for ferroelectricity. Model Hamiltonian simulations on PbZr1−x Tix O3 (PZT) alloys also support the formation of polarization domains for ferroelectricity thin films only a few unit cells thick [174, 175]. These two theoretical approaches, however, lack the atomic resolution that might be fundamental at the nanoscale range. First-principles simulations would provide invaluable information about the domain-wall structure, and the energy balance at the atomic level, helping to sort out the discussion about the generality of the formation of polydomain phases and the different effects involved. In order to study from first principles the breaking up into domains of ferroelectric ultrathin films we have performed simulations on typical BaTiO3 and PbTiO3 capacitors with SrRuO3 electrodes. With this study we aim to provide some insights, not only on which factors favor or hinder the formation of polydomain phases, but also about the existence of a particular structure of nanosized ferroelectric domains. Results reported in this Chapter have been published in Ref. [55]. 5.2 System and computational details We have performed first principles simulations within the local density approximation to the density functional theory and the numerical atomic orbital method as implemented in the Siesta code [121]. Our starting point is a reference non polar heterostructure built sandwiching a ferroelectric layer (BaTiO3 or PbTiO3 ) with a thickness of m unit cells, between 5.5-unit-cells-thick SrRuO3 electrodes. We assumed a TiO2 /SrO interface since the volatility of Ru makes this the most likely interface to form during the growth process in experiments. The reference non-polar structure is obtained relaxing both the atomic coordinates and out-of-plane stress of the capacitor while imposing a mirror symmetry plane located at the TiO2 layer in the middle of the ferroelectric layer. Polydomain supercells are build replicating the reference non-polar structure Nx times along the [100] direction, where Nx ranges from 2 to 8. Due to the periodic boundary conditions Nx determines the periodicity of the domain structure and we will refer to it either way throughout the following sections. Then, a soft mode distortion of the bulk tetragonal phase is superimposed to the BaTiO3 or PbTiO3 layers of the previous non-polar configuration, so the polarization points upwards in half of the superlattice and downwards in the other half [see inset of Fig. 5.1(a)]. For the BaTiO3 capacitors, the twinning on both the AO (Ba-centred), and TiO2 (Ti-centred) planes is considered. In the case of PbTiO3 , calculations on bulk show that PbO domain walls are clearly preferred [61] and are the only option considered here. The most stable polydomain configuration is obtained relaxing the atomic positions of all the ions, both in the electrode and in the ferroelectric thin film, until the maximum component of the force on any atom is smaller than 0.01 eV/Å (for BaTiO3 capacitors 5.3. Structure of polarization domains in ferroelectric thin films 137 with m = 2 and PbTiO3 capacitors with m = 4) or 0.04 eV/Å (for BaTiO3 capacitors with m = 4). In these system, differences in energy between relevant phases are tiny (eight orders of magnitude smaller than the absolute value of the energy), requiring very accurate computations to resolve reliably the relative phase ordering. In order to achieve the required accuracy, electronic density, Hartree, and exchange-correlation potentials are computed in a uniform real space grid, with an equivalent plane-wave cutoff of 400 Ry. We used a Nkx × 12 × 1 Monkhorst-Pack mesh for all the Brillouin zone integrations, where Nkx = N12x except for the interface with Nx =8, where Nkx = 2. Details on pseudopotentials and basis set used can be found in Ref. [124]. 5.3 Structure of polarization domains in ferroelectric thin films Our calculations support the stabilization of a polydomain phase in films with a thickness below the critical one for a monodomain configuration. This phases display an exceptionally small periodicity below the previous critical thickness [see Fig. 5.1(a) for the case of a BaTiO3 capacitor], in good agreement with the results obtained with Landau theory [172]. Within our computational parameters the critical thicknesses for the stability of a monodomain polarization in the BaTiO3 and PbTiO3 capacitors are m = 4 and m = 8 respectively. For the same ferroelectric material and electrodes our simulations prove that for a two-unit-cell-thick film (m = 2) in the case of BaTiO3 and a four-unit-cell thick (m = 4) in the case of PbTiO3 , the extra source of screening due to the formation of polarization domains is efficient provided that the domain period is between two and three times the thickness of the film. Landau theory models are indeed in remarkable agreement with our first-principles simulations, predicting a critical thickness for BaTiO3 capacitors of m = 2 for polydomain phases and m = 6 for monodomain metaestability [172]. Within this regime, the energy cost of forming the domain wall is compensated by reduction of the net polarization charge at the interfaces. In the particular case of PbTiO3 , both the absence of polydomain structures for m = 2 and its existence for m = 4 is in perfect agreement with x-ray scattering experiments in PbTiO3 thin films on a SrTiO3 substrate [170]. Figure 5.1(a) shows the relative energy of the polydomain phases in the BaTiO3 capacitors with respect to the position of the domain wall and the domain periodicity. For the BaTiO3 two possible domain walls where simulated, displaying twining on the BaO or TiO2 planes. As in 180◦ stripe-domains in bulk [61], the Ba-centered wall configuration is preferred. The energy difference between the most stable polydomain and the paraelectric phase for a BaTiO3 capacitor with m = 2 is very small, of the order of 1.5 meV (' 16 K) for the whole supercell. For this thickness there is essentially no energy difference between domains of lateral periods Nx = 4 and 6, suggesting that both might be equally present in a sample. Model Hamiltonian simulations on ferroelectric 138 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors Figure 5.1: Difference in energy between polydomain and paraelectric phases as a function of (a) the domain period Nx for a BaTiO3 thin film two unit cells thick (m = 2), and (b) the thickness of the ferroelectric film for a capacitor with Nx = 4. The energy of the paraelectric phase (dotted line) is taken as reference. First-principles results for both Ba-centred (circles, solid line) and Ti-centred (squares, dashed) domain walls are shown. In (a) differences in energies between local minima of the polydomain phase are represented by error bars. Inset, structure of the ferroelectric capacitor considered. Nx is the stripe period and m is the thickness of the ferroelectric thin film, in number of unit cells of the ferroelectric perovskite oxide. In (b) the result for the most stable monodomain configuration is also shown (triangle). Full symbols correspond to constrained relaxations where no in-plane displacements are allowed. thin films with larger thicknesses demonstrate that the energy versus domain periodicity landscape is indeed very flat [176]. Heating or cooling processes might help the system to overcome potential energy barriers and activate the transition between them. Although the conductive nature of the substrate is different, this fact might provide an extra source of explanation [175] for the intriguing richness in behavior of the stripe domain patterns observed experimentally in PbTiO3 thin films grown on SrTiO3 , where two different periods coexisted [170]. (Note that our ratio between domain periods, 1.5, is close to the experimental factor 1.4 for the so-called α and β phases in Ref. [170].) The energy differences between polydomain and paraelectric phases increase very quickly with thickness [Fig. 5.1(b)] and amounts to 120 (80) meV for a m = 4 BaTiO3 capacitor with a domain periodicity of Nx = 4 and Ba-centered (Ti-centered) domain walls (note these energies are per domain period, while values reported in Fig. 5.1(b) 5.3. Structure of polarization domains in ferroelectric thin films 139 Figure 5.2: Schematic representation of the atomic relaxations in patterns of domains of closure in BaTiO3 /SrRuO3 capacitors with domain period of Nx = 4 (a), and Nx = 6 (b). Balls, representing atoms, are located at the positions of the reference paraelectric phase. Atomic displacements for the polydomain configuration after relaxation are represented by arrows, whose magnitude can be gauged with respect to the displacements in the bulk tetragonal phase of BaTiO3 at the scale on the left. Only displacements of cations are displayed for clarity. Dotted lines indicate the position of the domain wall. Only Ba-centred domains are shown. Similar results are obtained for Ti-centred domains. have all been divided by Nx in order to compare with monodomain and paraelectric configurations). For this size, the polydomain phases are more stable than the monodomain configuration, itself more stable than the paraelectric phase by 20 meV. The minimum energy structures of these ferroelectric capacitors, shown in Fig. 5.2 for BaTiO3 capacitors and Fig. 5.3 for PbTiO3 capacitors, display the closure domain configuration proposed by Landau and Lifshitz [57] and Kittel [58] for some magnetic systems. At the center of the ferroelectric layer, the displacement of the atoms and therefore the corresponding local dipoles, point normal to the interface (coordinate z), as expected for 180◦ stripe domains. However, upon approaching the ferroelectric/electrode interface a tilt towards [100] is observed. In PbTiO3 capacitors, the tilt of Pb atoms is as large as to close the polarization flux within the ferroelectric layer, resembling very much the closure domains in ferromagnets. Similar domain patterns have been found using a first-principles effective Hamiltonian for PZT ceramics [174, 175]. However, in these simulations composition of PZT is very close to its morphotropic phase boundary 140 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors Figure 5.3: Schematic representation of the atomic relaxations in patterns of domains of closure in PbTiO3 /SrRuO3 capacitors with domain period of Nx = 6 and m = 4. Balls, representing atoms, are located at the positions of the reference non polar phase. Atomic displacements for the polydomain configuration after relaxation are represented by arrows. Only displacements of cations are displayed for clarity. Dotted lines indicate the position of the domain wall. (x = 0.5 in Ref. [174] and x = 0.6 in Ref. [175], while morphotropic phase boundary lies at x = 0.52). This makes rotation of the polarization less costly than in PbTiO3 , which in bulk displays a tetragonal c phase and for which the strain imposed by the SrTiO3 substrate is even slightly compressive (-0.5% within our simulations). On the other hand, domains of closure in the PbTiO3 capacitors can be regarded as formed by 90◦ domain walls, which are found to be more stable than 180◦ domain walls in bulk [61]. Remarkable differences are found between the domains of closure in the PbTiO3 and BaTiO3 capacitors. In the latter, the domains are not closed by the surface layer of the ferroelectric, as in PbTiO3 or PZT [174, 175], but by the in-plane displacements of the Sr and O atoms at the first layer of the electrode, which yield a closure domain pattern, with 90◦ domain walls with the z-oriented domains inside the film. The in-plane displacements of the atoms at the interfacial SrO layer, although small in magnitude, stabilize the domain structure. If a constrained relaxation of the BaTiO3 capacitors is performed in which the in-plane forces on all the atoms are artificially eliminated, the atoms move 5.3. Structure of polarization domains in ferroelectric thin films 141 Figure 5.4: Measurement of the polarization in the ferroelectric layer as a function of position along the [100] direction of the capacitor. (a) Definition of the average change in distance ∆ between Ti and apical O in a chain along [001]. In every case, the atomic positions correspond to the lowest energy structure. A positive value of ∆ means a polarization pointing upward. Profile of the normalized averaged change in distance along z as a function of the position of the chain for a BaTiO3 /SrRuO3 capacitor of domain period Nx = 4 (b) and a PbTiO3 /SrRuO3 capacitor of domain period Nx = 6 (c). The chains are numbered as indicated in Fig. 5.2 and 5.3. For the BaTiO3 -based capacitor (b), results are shown for both m = 2 (dashed line) and m = 4 (dot-dashed). Dotted lines represent the position of the domain walls. back to the paraelectric positions for m = 2, or to a structure comparable in energy to the most stable monodomain configuration for m = 4 [Fig. 5.1(b)]. Whether the in-plane displacement is allowed or not might partially explain the very different configurations found experimentally in related heterostructures: Lichtensteiger et al., using the same experimental setup, have observed how high-quality ultrathin films of PbTiO3 grown on Nb-SrTiO3 electrodes remain in a monodomain configuration [54] (although with reduced polarization and tetragonality) whereas they form domains when the electrode is replaced by La0.67 Sr0.33 MnO3 [169]. The same domain formation is suggested for Pb(Zr0.2 Ti0.8 )O3 on SrRuO3 [177]. In contrast to the metallic relaxations in monodomain configurations, where ionic displacements penetrate into the metal over a distance of two or three unit cells [168, 50], in polydomain capacitors the displacements beyond the second RuO2 layer are negligible, an indication of more effective screening produced by the domains of closure. The polarization profile of polydomain structures can be estimated from the structural calculations. Figure 5.4 displays how much the polar distortion along z is changed by the presence of a domain pattern. We define ∆ as the average of the change of distance, with respect the most stable non polar configuration, between a Ti atom and the nearest O atom lying on top along the z direction (cf. Ref. [61]), normalized with 142 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors respect to the short Ti-O distance in the bulk tetragonal phase. ∆norm is a very sensitive indicator of the polar order: it is zero as long as the atoms lie in the non polar position and tends to unity as the full bulk polar distortion is attained. Figure 5.4 shows a very narrow 180◦ domain wall for the BaTiO3 capacitor, about a lattice constant wide, across which the polar distortion symmetrically reverses its sign. A smoother domain wall is observed in the case of PbTiO3 , very much in the fashion predicted from continuum Landau-Ginzburg models for ferroelectric thin films close to the monodomainpolydomain transition [178]. In contrast to 180◦ domains in bulk [61], where the ferroelectric distortion fully recovers its bulk value by the second atomic plane far away from the domain wall, here the finite size of the ferroelectric layer limits the value of the polarization at the center of the domains. Polarization in BaTiO3 capacitors only amounts to 13% of the bulk value at the center of each domain for a m = 2 thickness, about one order of magnitude smaller than in bulk. The mean polarization increases with thickness, and already amounts to 60% for a four-unit-cells-thick (m = 4) thin film. In the case of PbTiO3 capacitors, already for the smallest thickness supporting polydomain structures (m = 4), polarization in the center of the domains amounts more than 70% of the bulk value, suggesting an extremely efficient screening by the domains of closure. 5.4 Role of the electrodes on the formation of polarization domains Domains of closure are a very favorable configuration. So favorable indeed, that when this structure cannot be formed by in-plane atomic displacements within the ferroelectric layer (due to in-plane strain, very uniaxial material, etc.) the formation of domains of closure can be assisted by interfacial atoms belonging to the electrodes. A direct way to prove the polarizability of the interfacial SrO layer is the calculation of the dynamical charges of the atoms lying within this layer. We saw in Chapter 1 that the effective charge of a given atom i is defined as ∂Pα ∗ Zi,αβ =Ω , (5.1) ∂xi,β E=0 where α and β indicate Cartesian directions. Typically, an effective charge calculation involves calculations of changes in the polarization via its Berry phase definition [179], when the atom of interest is displaced with respect to a reference configuration. However measurements of the polarization via the Berry phase is only possible in insulating materials, which is not the case of our capacitors. Alternatively, the classic procedure developed by R. Martin and K. Kunc [180] for the calculation of dynamical charges can be applied. Within this approach effective charges of bulk materials are obtained building a supercell containing several unit cells of the material. Then symmetric atomic displacements, δxi,α , are induced in two equivalent atoms sufficiently far away one from the other. The symmetric displacements create opposite dipole densities di,β at each atomic plane, 5.4. Role of the electrodes on the formation of polarization domains 143 Table 5.1: (3,3) component of the effective charges of the SrO layer at the PbTiO3 /SrRuO3 interface in comparison with those in bulk SrTiO3 . Values between brackets are the Born effective charges calculated by means of the Berry phase method. bulk SrTiO3 Interfacial SrO ∗ ZSr 2.41 (2.52) 1.62 di,β = −2.49 ∗ ZO1 (−5.95) ∗ Zi,αβ δxi,α , (5.2) S where S is the area of the supercell perpendicular to its elongated axis. The opposite dipole densities, in turn, induce two potential steps of opposite sign [see Fig. 5.5(a)] at the sites of each displaced atom di,β . (5.3) ∞ 0 The symmetric distortion avoids the development of depolarizing fields inside the supercell. The use of a sufficiently large supercell is required in order to recover a flat electrostatic potential to accurately measure the potential step. The effective charge of the displaced atom can then be calculated as ∆V = ∆V S∞ 0 , (5.4) δxα where, in this case, β is necessarily the direction parallel to the elongated axis of the supercell. Since ions are not allowed to relax after the atoms of interest have been displaced by hand, the electronic relative permitivity of the material ∞ should be used in Eq. 5.4. We have used the electronic permitivity of SrTiO3 (∞ = 6.15) for the estimation of the effective charges of the interfacial SrO layer. Nanosmoothed profiles of the electrostatic potential obtained using this method, after a displacement of δz = 0.05 Bohr of the Sr atom in bulk SrTiO3 and SrRuO3 are shown in Fig. 5.5(a) as a solid and a dashed line respectively. The corresponding values of the (3,3) component of the effective charges are reported in Table 5.1 for SrTiO3 (for SrRuO3 the potential drop, and correspondingly, the effective charges are negligible, as expected for a metallic material). Applying this method for the PbTiO3 /SrRuO3 ferroelectric capacitor (using the centrosymmetric configuration as the reference structure) we obtain the potential profile shown in Fig. 5.5(b). The comparison of the corresponding effective charges with the bulk ones, all gathered in Table 5.1, shows that atoms at the interfacial SrO layer display sizable effective charges. Although the dynamical charges of the SrO layer are not far from the nominal ones, they are clearly not zero, as would corresponds to a metal, and constitute an indication of the polarizability of the interfacial region. ∗ = Zαβ 144 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors 0.2 SrTiO3 SrRuO3 VH (V) 0.1 ∆V < 1 mV 0.0 -0.1 ∆V = 125 mV -0.2 SrO BO2 SrO BO2 SrO BO2 SrO BO2 SrO BO2 SrO BO2 SrO BO2 BO2 SrO BO2 (a) -0.3 0.10 ∆V = 129 mV VH (V) 0.05 ∆V = 84 mV 0.00 -0.05 (b) Sr displacement O displacement RuO2 SrO RuO2 SrO RuO2 SrO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 PbO TiO2 SrO RuO2 SrO RuO2 SrO RuO2 -0.10 Figure 5.5: Nanosmoothed electrostatic potential of (a) SrTiO3 and SrRuO3 supercells and (b) SrRuO3 /PbTiO3 capacitor, after two Sr or O atoms have been displaced symmetrically 0.05 Bohr out of their reference positions. The resemblance of this SrO layer to SrO in bulk SrTiO3 can also be appreciated from the analysis of the projected density of states displayed in Fig. 5.6. The SrO layer closest to the interface displays a dramatic drop of the DOS at the Fermi level and a simultaneous rise of a peak at about -5 eV, with the overall PDOS resembling that of bulk SrTiO3 . The enhanced polarizability of Sr in interfaces with ferroelectric materials has already been observed before. Similar behaviour was found in AO/ATiO3 heterostructures [124], where A = Ba or Sr. Both first-principles computations [71] and experimental measurements [181] have shown that SrTiO3 is highly polarizable when combined with BaTiO3 in heterostructures. 5.4. Role of the electrodes on the formation of polarization domains 145 Figure 5.6: Projected density of states on all the atoms as a function of the distance to the interface for the SrRuO3 /BaTiO3 paraelectric heterostructure. (a) Schematic view of the basic unit cell considered in our simulations. The reflection planes at the central RuO2 layer in the electrode and at the central TiO2 layer in the ferroelectric are shown. The layer by layer [numbered as in (a)] PDOS for the unpolarized interface is shown for the cations in (b) and for the O in (c). PDOS of bulk SrRuO3 , BaTiO3 , and SrTiO3 are also plotted for comparison. All the energies have been rigidly displaced in order to align the Fermi energy (vertical dashed line) with zero. Only the projection on the atoms in the bottom half of the supercell is shown. The projection on the atoms in the top half is identical due to the existence of the reflection planes shown in (a). 146 5.5 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors Screening of the depolarizing field Figure 5.7: Map of the nanosmoothed electrostatic potential in a two-unit-cells-thick BaTiO3 /SrRuO3 ferroelectric capacitor with a stripe period of Nx = 4 (a), and Nx = 6 (b). The arrows represent the atomic displacements with respect the paraelectric phase as in Fig. 5.2. Only the displacements of the cations are shown for simplicity. Full lines are a schematic representation of the domains of closure, while dashed lines mark the position of the BaTiO3 /SrRuO3 interface. Ideally, closure domains do not produce any polarization charge anywhere since the normal component of the polarization is preserved across any domain wall. Therefore the depolarizing field should vanish everywhere [58], and a nearly constant electrostatic potential is expected. To further check this point we plot in Fig. 5.7 the electrostatic potential for the BaTiO3 capacitor, nanosmoothed [106, 108] along z and as a function of the position along the [100] direction. No nanosmoothing is performed along x. For a stripe of thickness m = 2 and period Nx = 4, the potential is essentially flat at the center of the domain, in contrast to the depolarizing field reported for monodomain configurations [53]. A direct comparison between the electrostatic potential in the center of a domain and that in a monodomain capacitor is shown in Fig. 5.8 for a BaTiO3 /SrRuO3 capacitor with a thickness of the ferroelectric of m = 4 unit cells and a domain periodicity of Nx = 4 unit cells in the case of the polydomain structure. The field in the center of the domains is significantly smaller in the later – about one third – than that in 5.6. Theoretical prediction and experimental observation of closure domains 147 0.2 monodomain polydomain VH (V) 0.1 0.0 -0.1 SrO RuO2 SrO RuO2 SrO TiO2 BaO TiO2 BaO TiO2 BaO TiO2 BaO TiO2 SrO RuO2 SrO RuO2 SrO RuO2 SrO -0.2 Figure 5.8: Profile of the nanosmoothed electrostatic potential for BaTiO3 /SrRuO3 in a monodomain phase (solid line) and in the center of a domain in a polydomain configuration (dashed line). the monodomain capacitor, despite the larger polarization attained in the polydomain structure (29 µC/cm2 , in contrast to the 13 µC/cm2 in the monodomain case). In Fig. 5.7 we also observe a large microscopic field along [100] inside the domains of closure at the metal-ferroelectric interface. The origin of this field is the variation of the magnitude of P as the dipoles rotate from the center of the ferroelectric film to the closure domains in the interface region. Besides, after nanosmoothing in z a residual depolarizing field along [001] is identified in the neighborhood of the domain wall, decaying rapidly away from it. This last field might be responsible for the lowering of the polarization with respect to bulk shown in Fig. 5.4. Both fields might play an important role in the fatigue of ferroelectric capacitors, the most serious device problem in ferroelectric thin films [99]. In particular we identify at the ferroelectric/electrode interface the preferred points of migration of charged defects, which pin the domain walls and inhibit their motion [182]. The depolarizing field at the center of the domain increases with the domain period; it starts to be appreciable for Nx = 6 [Fig. 5.7(b)] and finally destabilizes the ferroelectric distortions for Nx = 8, as shown in Fig. 5.1(a). 5.6 Theoretical prediction and experimental observation of closure domains in ferroelectric thin films Domains of closure in ferroelectric thin films were unexpected to form due to the large elastic coupling of the polarization with the strain, which in these materials play the role analogous to the magnetocrystaline anisotropy in ferromagnets [183]. We have seen throughout this Chapter that despite this common assumption, in the last years this closure domains in ferroelectric thin films have been predicted to exist independently of the theoretical approach, for ferroelectric thin films made of different materials and regardless of the electrostatic boundary conditions. Domains of closure have been found using a first-principles-based effective Hamiltonian for PZT symmetrically [174] and asymmetrically [175] screened (grown on a nonconducting substrate and with a metal with a dead layer as top electrode), and using a Landau-Ginzburg phenomenological 148 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors approach for a PbTiO3 thin film [56], both asymmetrically and symmetrically coated with insulating SrTiO3 . Here, we observe the formation of domains of closure even for a symmetrical metal/ferroelectric/metal capacitor, with uniaxial ferroelectrics that were expected to profoundly dislike rotating the polarization and formation of in-plane dipoles [174], and where the metallic plates should provide significant screening. Besides, the formation of ferromagnetic-like closure domains in two very different ways – by rotation towards the in-plane direction of the polarization within the ferroelectric layer (in PbTiO3 ) or assisted by in-plane displacements of the interfacial electrode layer (in BaTiO3 ) – suggest that this kind of structures, previously thought to be unlikely to occur in ferroelectric materials, could be a much more general result. This conclusion has been further reinforced after the observation of closure domains in other systems, such as ferroelectric/insulator superlattices (see Chapter 6) or even free standing slabs [184]. In spite of all the theoretical predictions, the experimental observation of domains of closure in ferroelectric thin films have been elusive. Very recently, the development of the spherical aberration correction in transmission electron microscopy (TEM) [74] have allowed the determination of atomic structure and composition with subangstrom resolution. With this technique the ferroelectric polarization can be directly determined from the atomic displacements measured in atomic-resolution TEM images. This new technique finally led to the direct observation of closure domains in PbZr0.2 Ti0.8 O3 thin film grown on SrTiO3 [66]. Fig. 5.9 shows TEM images of the sample close to the boundary between two 180◦ domains. Upon approaching the interface local dipoles (measured as the relative displacement of Ti and Sr atoms with respect to the oxygen cages) rotate in order to close the polarization flux and avoid the accumulation of bound charges. Although scaled to the much larger thickness of the experimental sample, the flux-closure structure bears a great similarity with the gradual dipole rotation we observe in the capacitor of the parent ferroelectric material PbTiO3 . Similar structures have also been found between 109◦ domain walls in BiFeO3 on insulating TbScO3 substrates [67]. All these researches provide an illustrative example of the predictive power of today’s theoretical methods and the feasibility of first-principles simulations on systems which are directly comparable with experiments. 5.7 Conclusions The perfect screening provided by the formation of polarization domains in ferroelectric capacitors has been something given for granted for a long time. The energetic balance and particular structure at the atomic level of domain walls for ferroelectric thin films, however, was often disregarded. Our simulations prove that the screening is so good indeed that it brings the limit thickness of ferroelectricity virtually to zero. Strictly speaking, although we have demonstrated that the domains are stable, it is not clear whether in this limit the capacitor as a whole can be called ferroelectric since, for this, the polarization has to be switchable under external electric fields [177, 174]. However the great stability of the structures 5.7. Conclusions 149 Figure 5.9: (Left) Atomic-resolution TEM image of a closure domain with continuous dipole rotation in PbZr0.2 Ti0.8 O3 close to the interface to the SrTiO3 substrate. The interface is marked by a horizontal dashed line (I), which is determined on the basis of a SrRuO3 marker layer with a nominal thickness of 1.5 unit cells at the interface. The RuO2 marker layer is also indicated. Two larger domains with out-of-plane polarization (indicated by arrows) can be identified. In the lower part, close to the interface, a triangular domain with in-plane polarization can be seen. The inset at the lower right shows a calculated image demonstrating the excellent match between the atomic model and the specimen structure. (Right) Map of the atomic displacement vectors. The displacement of the Zr-Ti atoms (arrows) from the center of the projected oxygen octahedra is shown here superposed on the TEM image. To enhance contrast, the gray scale is converted into a false-color representation. The length of the arrows represents the modulus of the displacements with respect to the yellow scale bar in the lower left corner. Note the continuous rotation of the dipole directions from “down” to “up”, which closes the electric flux of the two 180◦ domains. Reprinted with permission from Ref. [66]. 150 Chapter 5. Ferromagnetic-like closure domains in ferroelectric capacitors obtained in this work suggest that polarization of domains would still be the most stable configuration for thicknesses well above the critical thickness of monodomain ferroelectricity. Our calculations provide insightful results on the energetic, structural and electronic properties of ferromagnetic-like closure domains in ultrathin capacitors. This kind of domain structure, that was first predicted theoretically but had not been detected experimentally, has just been observed for the first time in PbZr0.2 Ti0.8 O3 [66] and BiFeO3 thin films [67]. The agreement between different theoretical approaches and experimental measurements in this case is remarkable and strongly suggest that closure domains in ferroelectric thin films might be a much more general result than previously thought. We have also provided some hints to explain why some systems break into domains while others remain in a monodomain configuration. We also predict the preferential sites for pinning charged defects, important for understanding the fatigue of thin films. Both issues are of vital importance in the integration of ferroelectric in practical devices. Chapter 6 PbTiO3/SrTiO3 superlattices 6.1 Introduction As it was already discussed in Chapter 1 the growth of superlattices composed of thin layers of ABO3 perovskites with different physical properties has become one the the most promising paths to exploit the coupling between instabilities in these compounds in order to engineer new functionalities. The fascination for layered system comes from the fact that the properties of epitaxial structures, made by stacking different perovskites, are not a simple combination of the properties of the constituent materials, but exotic phenomena might emerge that fully rely on interfacial effects. These phenomena arise as a consequence of the delicate balance between instabilities in perovskite oxides, that is altered by the presence of an interface, the interplay between the effects of strain and electrostatic interactions between the layers, and the coupling of different structural instabilities in the reduced symmetry environment of the interface [46]. The intrinsic interfacial character of these properties allow their tunning, no only by external electrical and strain [38] fields, but also by changing the chemical environment through the use of different materials and periodicities in the stack. Of course, the combination of ferroelectric perovskites with other materials in layered structures have attracted a lot of interest during the last few years [99, 7]. If ferroelectricity is preserved in the layered system it would permit, for instance, the use of electric fields to control other functional properties of the superlattice. In the pursuit of this kind of functionalities and the improvement of the performance of ferroelectric thin films [23], ferroelectric materials are being combined with different paraelectric (or incipient ferroelectric) ABO3 perovskites. For a long time the focus was on the electrostatic coupling between the layers of the superlattice, and the interplay with the epitaxial strain. The most studied case was BaTiO3 /SrTiO3 , where the structure adopts a uniformly polarized state, with the polarization value determined by the competition between the energy cost of polarizing the SrTiO3 layers and the energy gain in preserving the polarization in the BaTiO3 (BTO) layers [71]. More recently the interest has evolved to include also the interaction 151 152 Chapter 6. PbTiO3 /SrTiO3 superlattices between FE and AFD modes in perovskite related systems [185]. A startling system in the recent literature is the (PbTiO3 )m /(SrTiO3 )n [(PTO)m /(STO)n ] superlattice. It was theoretically predicted and experimentally observed that the polarization, tetragonality and phase transition temperature of the system can be monitored with the number of PTO layers, m. As the volume fraction of PTO is reduced, the penalty imposed by the poling of the STO becomes dominant in the energy balance of the system and the polarization of the superlattice decreases [186, 187]. This trend, that can be accounted by simple electrostatic models, breaks down in the limit of ultrashort periods, for which PTO/STO superlattices exhibit an unexpected recovery of ferroelectricity that cannot be accounted for by simple electrostatic considerations alone [19]. First-principles calculations found that the ground state of the system is not purely ferroelectric, but involves a trilinear coupling term between two AFD modes, that correspond to in-phase (AFDzi ) and out-of-phase (AFDzo ) rotations of the oxygen octahedra around the z axis, that induce a polar FE distortion (Pz ) in a way compatible with improper ferroelectricity [19]. In recent experiments, Zubko and coworkers [188] have studied the dependence of the structural and dielectic properties of PbTiO3 /SrTiO3 superlattices as a function of the volume fraction of PbTiO3 , the electrodes, and the applied electric fields. While the results of the superlattices asymmetrically sandwiched between Nb-doped SrTiO3 (bottom) and gold (top) electrodes were consistent with a monodomain configuration, those corresponding to the use of symmetrically coated SrRuO3 electrodes (both top and bottom) suggested a polydomain phase with domain wall motion. Previously, 180◦ stripe domains were also detected in PbTiO3 thin films grown on SrTiO3 (001) substrates. The domain structure was characterized both in reciprocal space (strong satellites around PbTiO3 Bragg peaks in synchrotron x-ray scattering measurements) [189, 190, 170], and in real space (images recorded by atomic force microscopy) [171]. In these works, the equilibrium polarization structure of epitaxial films undergo a sequence of changes as a function of the thickness of the PbTiO3 layer and temperature. The phase transitions involve (i) polydomain phases with different stripe periods (the so-called Fα phase with a short period, and the Fβ phase with a period √ 2 longer), (ii) the monodomain phase, Fγ , for thicker films near room temperature, (iii) and the paraelectric phase at high temperatures. It is clear, from this discussion and in view of the results of Chapter 5, that different phases are in close competition, and a small change in one of the parameters (cooling temperature, thickness, choice of electrode, etc.) might help to incline the balance towards one of the local minima displayed in the energy landscape, yielding a different polarization structure. In this Chapter we explore the phase diagram of the PTO/STO superlattices systems to gain further insight about the different instabilities present in the superlattices and their coupling. First we study the mixed coupling between the polar, the AFD instabilities and the strain in monodomain phases in order to find new paths to engineer functional properties in this system. In a second step we explore the formation of polarization domains and the structure of domain walls in PTO/STO superlattices, 6.2. Structure and computational details 153 considering the influence of the lateral domain size, orientation and energy of domain walls, and the influence of AFD instabilities in these structures. 6.2 Structure and computational details For this study we perform first principles simulations of (PTO)n /(STO)n superlattices, within the local density approximation (LDA) to the density functional theory (DFT) using the Siesta code [121]. Real space integrations are computed in a uniform grid, with an equivalent plane-wave cutoff of 1200 Ry. For the Brillouin zone integrations we use a Monkhorst-Pack sampling equivalent to 12 × 12 × 12 in a five atom perovskite unit cell. Details on the norm-conserving pseudopotentials and the basis set used can be found in Ref. [124]. The superlattices are simulated by means of a supercell approach, where we repeat periodically in space a simulation box, as was explained in Sec. 2.6. The basic building block of our structures is built stacking alternating layers of PTO and STO along the [001] direction (z axis) with a thickness of n unit cells for a global periodicity of (n/n) [Fig. 6.1(a)]. Monodomain superlattices have been simulated with n ranging from one to three. For polydomain superlattices a (3/3) periodicity was chosen because it has been experimentally proved that this is a critical periodicity beyond which the PbTiO3 layers in the superlattices are electrostatically decoupled [65]. Besides, first works on these systems suggested that, for short-period superlattices, a ratio between the number of layers of PbTiO3 and SrTiO3 close to 1 represents the borderline case between a “normal” behaviour and the appearance of the improper ferroelectricity [99]. For each periodicity, a reference structure is obtained imposing a mirror symemtry plane in the middle of the PbTiO3 layer and relaxing both atomic positions and the out-of-plane lattice vector until the value of the Hellmann-Feynman forces and zz stress tensor components fall below 0.01 eV/Å and 0.0001 eV/Å3 respectively. From this starting structure different configurations have been constructed and then relaxed. The mechanical boundary conditions imposed by the substrate are implicitly treated by fixing the in-plane lattice constant, ak . The use of periodic boundary conditions imposes short-circuit electrical condition across the whole unit cell. For the simulation of monodomain configurations, in-plane lattice vectors should be doubled to account for the condensation of AFD instabilities. With the (2 × 2) in-plane periodicity, TiO6 octahedra are allowed both to rotate an angle φ around the z-axis or to tilt an angle θ around an axis contained in the (x, y) plane [Fig. 6.1(b)]. After the in-plane doubling of the building block cell, symmetry is broken displacing the atoms by hand and the whole structure (atoms and out-of-plane lattice vector) is relaxed again. Non-polar structures are obtained constraining the atomic displacements to avoid the development of a polarization in any direction. For the simulation of polydomain configurations the reference structure in replicated Nx times in the [100] direction (x axis) and Ny times in the [010] direction (y axis). Due to the periodic boundary conditions used in the simulations, Nx determines the domain periodicity (or, equivalently the domain lateral size), while Ny allows to switch 154 Chapter 6. PbTiO3 /SrTiO3 superlattices Figure 6.1: (a) Squematic representation of a (2/2) PTO/STO superlattice. TiO6 octahedra are labeled according to the chemical identity of the first two neighbor layers of TiO2 planes, and the direction of the polarization. (b) Definition of the angles of rotation along the z axis, φ, and tilting along an axis in the (x, y) plane, θ, of the O octahedron. on (Ny = 2) and off (Ny = 1) the AFD instabilities. As it was done before for the study of ferroelectric capacitors in Chapter 5, an initial distortion is induced displacing atoms by hand, so the polarization points upwards in half of the superlattice and downwards in the other half. Initial AFD-like displacements are induced by hand for supercells with Ny = 2. Then the most stable polydomain structure for each domain lateral size is obtained relaxing the forces and out-of-plane stress. 6.3 Mixed ferroelectric-antiferrodistortive-strain coupling in the monodomain configuration For the (2/2) superlattice we have performed structural relaxations under different inplane strains, while keeping the square surface symmetry, to mimic the effect of some of the most common cubic substrates. The misfit strain is defined as ε= ak − a0 , a0 (6.1) where a0 is our LDA theoretical lattice constant of cubic bulk cubic PTO (3.892 Å). (Unless otherwise stated, throughout this Chapter strain is always given relative to the PTO layer.) The dependence of the polarization (inferred from the bulk Born effective charges and the local atomic displacements) with the epitaxial strain, Fig. 6.2(a), has some 6.3. Mixed FE-AFD-strain coupling in the monodomain configuration 155 Figure 6.2: (a) Polarization and (b) absolute value of the oxygen octahedra rotations and tiltings in monodomain (2/2) superlattices under different epitaxial strains, corresponding to the in-plane lattice constants of representative substrates. In (a), the insets represent schematically the orientation of polarization in the PTO (darker arrow) and STO (lighter arrow) layers. In (b), the rotation, φ, and tilting, θ, angles of the O octahedra (labeled as in Fig. 6.1) are represented as star-dotted and cross-dashed lines, respectively. 156 Chapter 6. PbTiO3 /SrTiO3 superlattices resemblances with the one already observed in strained bulk BTO [191], PTO [192], or PTO/PbZrO3 (1/1) superlattices [192]. For large compressive strains a homogeneous polarization (including the naturally paraelectric STO layer) is stabilized along the zdirection (the c-phase in Refs. [20, 191]). The polarization mismatch at the interface is always smaller than 0.5 µC/cm2 , highlighting the large electrostatic cost of a polarization discontinuity between the layers [71, 186, 193]. The price to pay for poling the STO layer is a reduction in the polarization of PTO with respect the bulk spontaneous value (90 µC/cm2 ). This value of the polarization, 90.35 µC/cm2 corresponds to the bulk tetragonal phase, with a = 3.855 Å and c = 4.071 Å. Imposing STO in-plane lattice constant a = 3.874 Å, then c = 4.028 Å and Pz = 82.52 µC/cm2 . On the opposite limit, for large tensile strains, the polarization in the most stable configuration lies in the plane along the [110] direction (aa-phase [20, 191]). Note that, in this case, there is no electrostatic restriction to keep the in-plane polarization at the same value in the PTO and STO layers. (Neither ∂Px /∂z nor ∂Py /∂z contribute to the divergence of the polarization.) Interestingly, there is an intermediate region of strains (around ε ≈ 0) where the polarization rotates continuously from the c to the aa-phase. In this range of strains, around that imposed by a STO substrate, in-plane and out-of-plane polarization coexist, giving rise to an r-phase [20, 191]. Both, the decrease of out-of-plane and the onset of the in-plane polarization, display the typical shape of a second-order phase transition. The appearance of a r-phase is a rather unexpected result since PTO is a tetragonal ferroelectric in bulk and the strain imposed by the STO substrate is even slightly negative (-0.5% within our simulations). Moreover, the existence of an r-phase in strained bulk PTO has not been reported in previous first-principles simulations at any value of the strain [192]. Our simulations suggest that, in order to reduce Pz , the rotation of the polarization is energetically less coslty than a monotonic reduction along [001]. This result is in agreement with previous simulations on BaTiO3 , which showed that rotation of the polarization was prefered over a change in its magnitud under the application of an external applied field [194]. We observe also a strong coupling between FE and AFD modes, that can be tuned by epitaxial strain [Fig. 6.2(b)]. For a fine analysis of the coupling, it is useful to label the O octahedra depending on the identity of the first two neighboring layers along the z-axis, and on the direction of the polarization, as is done in Fig. 6.1. In this way, we can define octahedra with three different enviroments: those between two PbO layers (labeled as PTO), those between two SrO layers (labeled as STO), and those at the interfaces, with SrO at one side and PbO at the other. As polarization of the superlattice breaks the inversion symmetry we should distinguish between the two different interfaces, thus we label as P+ (P− ) to the top (bottom) interface of the PTO layer with respect to the polarization direction. In the previous Figures we find that, similar to the case of FE distortions, AFD ones are strongly coupled with strain. Compressive strains favor the rotations of the octahedra and suppress tiltings, while tensile strains produce the opposite effect. This trend can be understood if we consider that the Ti-O bond is very rigid. Then, as strains 157 6.3. Mixed FE-AFD-strain coupling in the monodomain configuration Table 6.1: Relative energies of different monodomain configurations as a function of the periodicity of the supercell. GS stands for ground state. Energies per 5-atoms unit cell in meV. Paraelectric [110] [001] [111] (1/1) +15.3 +4.6 +1.2 GS (2/2) +12.8 +3.5 +3.1 GS (3/3) +9.7 +3.5 +4.0 GS Table 6.2: Polarization of the different monodomain configurations for superlattices as a function of the periodicity of the supercell. In-plane strain corresponding to a STO substrate (3.874 Å). AFD modes are allowed in the paraelectric phase. Polarizations in µC/cm2 . (1/1) (2/2) (3/3) PSTO PPTO PSTO PPTO PSTO PPTO Para. (0.0, 0.0, 0.0) (0.0, 0.0, 0.0) (0.0, 0.0, 0.0) (0.0, 0.0, 0.0) (0.0, 0.0, 0.0) (0.0, 0.0, 0.0) [110] [001] [111] (20.7, 20.7, 0.0) (31.4, 31.4, 0.0) (16.0, 16.0, 0.0) (34.5, 34.5, 0.0) (14.2, 14.2, 0.0) (35.9, 35.9, 0.0) (0.0, 0.0, 35.5) (0.0, 0.0, 35.0) (0.0, 0.0, 34.4) (0.0, 0.0, 34.8) (0.0, 0.0, 33.6) (0.0, 0.0, 34.3) (14.2, 14.2, 31.5) (23.3, 23.3, 31.1) (9.2, 9.2, 29.8) (29.5, 29.5, 30.4) (6.9, 6.9, 29.0) (31.8, 31.8, 30.3) are applied, the system allows the TiO6 octahedra to change orientation to maintain the Ti-O distance constant (see Fig. 3 of Ref. [3]). This is consistent with experimental results [195] where it is found that in most cases the AFD distortions are stabilized under hydrostatic pressure. 6.3.1 Periodicity dependence of FE-AFD coupling We have also carried out simulations for different periodicities, while keeping constant the PTO/STO volume fraction (n/m = 1) and fixing ak to the LDA theoretical one of SrTiO3 . Unconstrained and constrained structural optimizations were performed, where we imposed a purely out-of-plane or in-plane polarization on the superlattice, otherwise oxygen octahedra are allowed to rotate freely. Relative energies and polarizations of the PTO and STO layers are gathered in Tables 6.1 and 6.2 respectively. The ground state monodomain configuration displays both in-plane and out of plane polarizations, independently of n. Within the PTO layer, P lies close to the diagonal of the perovskite unit cell, especially for n ≥ 2 (configuration labeled as [111] in Table 6.2). The ground state structure can be considered as a condensation of FEz + FExy + AFDz + AFDxy 158 Chapter 6. PbTiO3 /SrTiO3 superlattices modes. For n = 1, the c and r-phase are essentially degenerated (the difference in energy, only 1.2 meV per 5-atoms unit cell, is within the accuracy of our simulations). The delicate competition was already observed by Bousquet et al., who found that at the ground state for (1/1) superlattices in Ref. [19] the phonon frequency of the mode involving in-plane distortions is only 6 cm−1 , very close indeed to become unstable. The small difference between the results in Table 6.1 and those in Ref. [19] can be ascribed to small changes in the methodology. In particular ak in Ref. [19] was fixed to the bulk LDA of SrTiO3 within a plane-wave (PW) simulation (3.84 Å [186]), slightly smaller than the corresponding value obtained with a numerical atomic orbital (NAO) code (3.874 Å), as we are doing here. Larger periodicities of the superlattice seems to increase the range of stability of the r-region, as the difference in energies between this phase and the rest increases, nevertheless examination of Fig. 6.2 shows that even for the (2/2) superlattices a small change in the mechanical boundary conditions can significantly alter the ground state of the system. In every case, Pz is nicely preserved at the PTO/STO interface, with a value between 30 and 35 µC/cm2 . On the other hand, the in-plane polarization increases with the reduction of n. Oxygen octahedra rotations, shown in Fig. 6.3, display a strong coupling with the polarization direction for all the studied periodicities. Tilting is suppressed in almost any case but for the ground state, where polarization direction is not constrained and lies close to the [111] direction. The strong coupling of polarization with oxygen octahedra around the z axis at the interfaces is clearly observed here: angle φ is clearly enhanced at the P+ interfaces and damped in the P− in [111] and [001] configurations (in [110] and paraelectric configuration there is no difference between P+ and P+ interfaces), in agreement with the covalent model described Sec. 6.3.3. 6.3.2 Emergence of an r-phase in PbTiO3 /SrTiO3 superlattices We observe that the coupling between different distortions together with the electrostatics of the superlattice gives rise to the appearance of a r-phase at intermediate strains. In fact our simulations suggest that in order to reduce the out-of-plane component of the polarization, Pz , to a value of around 30 µC/cm2 (the typical order of magnitude shown in Table 6.2), PbTiO3 prefers to rotate the direction of the polarization towards the [111] direction over a monotonic reduction along the [001] axis. This point was tested performing simulations of bulk PbTiO3 where polarization was constrained to lie along [111]. When forces and out-of-plane stress were relaxed while fixing the in-plane lattice constant to that of SrTiO3 (3.874 Å within our simulations), PbTiO3 was found to display a polarization along [111] of 53.1 µC/cm2 (the out-of-plane component being 31.0 µC/cm2 ). Calculations of the double well energies shown in Fig. 6.4 reveal that below an outof-plane component of the polarization of 31.8 µC/cm2 , a poling of PbTiO3 along the 6.3. Mixed FE-AFD-strain coupling in the monodomain configuration 159 Figure 6.3: Oxygen octahedra rotation (solid lines, squares) and tilting (dashed lines, diamonds) angles. On the leftmost part of the figure, schematic view of the atomic structure of the superlattices are shown. Direction of the polarization is indicated on the top of each panel. The same notation as in the main manuscript is used. 160 Chapter 6. PbTiO3 /SrTiO3 superlattices [111] direction is preferred over the monotonic reduction along [001]. 20 P along [111] Energy (meV) 0 -20 -40 -60 P along [001] 0 20 31.8 40 80 60 100 120 2 Pz (µC/cm ) Figure 6.4: Energy as a function of the out-of-plane component of the polarization for bulk tetragonal PbTiO3 displaying a polarization along [001] (red line) or [111] (black line). Dashed line indicates the threshold out-of-plane polarization below which a rotation of P towards the [111] direction is preferred over a monotonic reduction along [001]. The square (circle) correspond to a single point calculation of bulk PTO in which the atomic coordinates and unit cell are fixed to those of the PTO layer in the (3/3) [001] ([111]) superlattice. Last two data points (and only those) include AFD distortions. In all cases, in-plane lattice constant is fixed to the theoretical SrTiO3 one. All energies are given per 5-atoms unit cell. However the energy difference between the [001] and the [111] phases are too small to explain the energy differences between these phases in the superlattices, reported in Table 6.1. The increased stability of the [111] phase can be accounted for by including the AFD distortions in the analysis. Bulk tetragonal PbTiO3 ground state displays only the Γ point ferroelectric distortion. Nevertheless, constrained simulations show that when the polarization in bulk PTO is forced to decrease or rotate, AFD distortions emerge, decreasing the energy of the system. We have performed single point calculations on bulk PbTiO3 , but doubling the size of the unit cell along the three directions of space (i.e. using a 2 × 2 × 2 simulation cell with 40 atoms) freezing the coordinates to those found in the middle of the PbTiO3 layer in the (3/3) [001] and [111] superlattices. These two configurations, represented respectively by an square and a circle in Fig. 6.4, display oxygen octahedra rotations and their energies are below the double well curves of [001] and [111] phases, for which AFD instabilities were forbidden. The energy difference between these two configurations of bulk PTO is about 7 meV, in good agreement with the energies reported for the superlattices in Table 6.1. 6.3. Mixed FE-AFD-strain coupling in the monodomain configuration 6.3.3 161 Covalent model for the polarization-octahedra rotation coupling We have seen that the coupling of the oxygen octahedra rotations with strain can be understood in terms of steric effects (TiO6 octahedra rotate in order to accomodate inside the distorted cell), however, superimposed to the main strain effect there is an extra coupling with the polarization which is distinct for each of the octahedra types defined before. The largest difference is observed when strong compressive strains are applied: here the P+ octahedra rotate more than PTO and STO ones, while P− octahedra rotate much less. In order to understand these results let us discuss the origin of the coupling between between FE and AFD modes. Figure 6.5: (a) Diagram showing the change of distances between the Pb and O ions at the PTO/STO interface under compressive strain for a P+ TiO6 octahedra. Only one TiO2 plane and the Pb atoms directly underneath are represented. For the leftmost Ti, the full TiO6 octahedra is depicted by dashed blue lines. (b) same as in panel (a) but for a P− octahedra. Now, only the Pb atoms direcly on top are represented. Reduction of distance and reinforcement of the Pb-O bond is shown by full red lines while an increase in the Pb-O distance and weakening of the bond is shown by dotted lines. Green arrows represent out-of-plane displacement of Pb. Yellow arrows represent the in-plane displacement of O, consistent with an extra convalent contribution to TiO6 rotation. AFD distortions are usually regarded as purely steric phenomena, where the rotation of the octahedra takes place if the A-ion is small enough to let the B-O-B bond bend [196]. A polar distortion of the A cation along the positive z-axis for the P+ octahedra reduces the distance between the metal and the oxygen ions of the TiO2 plane immediately above [Fig. 6.5(a)]. Thus, according to a steric model we would expect that the P+ octahedron would rotate less than the P− one where the Pb ion moves away [Fig. 6.5(b)], as the free space around the oxygen ions is reduced in the former. However, Fig. 6.2(b) shows precisely the opposite trend: P+ displays a much increased rotation with respect to P− . Besides steric effects, we propose that as a consequence of the symmetry reduction at the interfaces the mixed AFD-FE-strain coupling in PTO/STO superlattices is driven by 162 Chapter 6. PbTiO3 /SrTiO3 superlattices a force of covalent nature. It is well known that a chemically active lone pair on the Pb ion, that allows for strong covalent hybridization with O, lies at the origin of FE in bulk PTO. Due to the coupling between FE and AFD distortions, not all the Pb-O bonds are equivalent leading to a reduction of energy. In particular, having two shorter (2.447 Å) and two longer (2.928 Å) bonds per Pb atom increases covalency with respect to having four equivalent bonds. For the P− octahedra, the polar distortion increases the Pb-O distances and the previous mechanism does not apply [Fig. 6.5(b)]. These results agree with recent ab-initio calculations that emphasize the role of covalent interactions in the origin of AFD distortions [197]. As the in-plane strain is increased, the polarization rotates away from the z axis and this coupling is reduced making the in-plane rotations small and similar for all octahedratypes when the values of the strain are larger than +1%. Under these tensile strains, the Pb displace in-plane and both P+ and P− become equivalent. From the point of view of symmetry this can be demonstrated considering the polar displacement of the Pb ions along the z-axis and the xy directions. In Fig. 6.6 we see that a horizontal reflection plane coinciding with the TiO2 plane transforms the P+ and P− octahedra into each other in the aa-phase, probing their equivalence. On the contrary no symmetry operation is found to relate the P+ and P− octahedra in the c-phase showing their differences in physical behavior. Figure 6.6: Diagrams showing the equivalence of the P+ and P− octahedra in the aaphase owing to the horizontal reflection plane associated to the TiO2 plane. In contrast no symmetry operation relates P+ and P− in the c-phase. 6.3. Mixed FE-AFD-strain coupling in the monodomain configuration 6.3.4 163 Piezoelectric response of the system σ (GPa) -0.08 -0.06 -0.04 -0.02 80 0 0.02 0.04 0.06 0.08 (a) 2 P (µC/cm ) 60 40 PTO Pz PTO 20 Pxy STO Pxy 0 20 15 (b) d (nC/N) 10 d11 5 d11 0 -5 PTO STO d31 -10 -15 -20 -0.08 -0.06 -0.04 -0.02 0 0.02 0.04 0.06 0.08 σ (GPa) Figure 6.7: Polarization (a) and piezoelectric constants (b) as a function of the in-plane stress for the PTO/STO (2/2) superlattice. From the analysis of the dependence of the polarization with respect to the strain, shown in Fig. 6.2, it follows that close to the c ↔ r ↔ aa phase transition series the electromechanical response of the system (d31 piezoelectric constant) should be greatly enhanced. The d31 and d11 piezoelectric constants were computed using the polarization, calculated from the Born effective charges and atomic displacemnts, and the in-plane stress, routinely available as an output of most common DFT codes. For the calculation of the piezoelectric constants, in-plane and out-of-plane polarizations were plotted as a function of the in-plane stress, σ1 in Voigt notation. The available points P (σ) were fitted to the characteristic curve of a ferroelectric-paraelectric second order phase transition [20] P = p A(σ − σ0 ), (6.2) where σ0 is the stress at which the polarization drops to zero. In-plane and out of plane 164 Chapter 6. PbTiO3 /SrTiO3 superlattices Figure 6.8: Piezoelectric coeficients of the PTO/STO (2/2) superlattice as a function of PTO strain. components of the polarization are fitted separately despite being naturally coupled, with all the coupling terms being hidden in the fitting constants A and σ0 . Despite this approximation the separate fittings match very accurately the calculated polarizations, as can be seen in Fig. 6.7(a). The piezoelectric constants were then computed as analytical derivatives of the fitting curves [shown in Fig. 6.7(b)]. Since in-plane polarization is mesured for both the PTO and STO layers, two d11 piezoelectric coeficients can be computed, being the effective d11 coefficient of the superlattice the average of them. Piezoelectric constants diverge at the phase transition strains (see Fig. 6.8), reaching values of more than 10 nC/N (around one hundred times larger than typical piezoelectric constants of Pb(Zr0.5 Ti0.5 )O3 ceramics [198]) at strains easily achievable in a laboratory. 6.4 Polydomain structures The continuity of the component of the polarization perpendicular to the PTO/STO interface in monodomain phases (see overlap of PzSTO and PzPTO curves in Fig. 6.2 or polarization values in Table 6.2) reflects the huge energy cost that would be associated with the formation of bound charges at the interface and the development of a depolarizing field. Minimization of the electrostatic energy in the monodomain phase is achieved poling the SrTiO3 layer and reducing and rotating the polarization in the PbTiO3 layer. We have seen in Chapter 1 how accumulation of bound charges can alternatively be screened by the formation of polarization domains. On the other hand one of the main conclusions of Chapter 5 was the the idea that closure domains are a very favorable structure in ferroelectric thin films, predicted to be formed in a great variety of ferroelectric materials and under a great range of screening degrees. It is thus reasonable to expect similar arrangements in the PTO/STO superlattices. It is the aim of this Section to investigate the particular structure of domains in the PTO/STO superlattices as well as their coupling with the different distortions detected in the monodomain phase. 165 6.4. Polydomain structures 70 60 Non-polar Energy (meV) 50 40 30 Monodomain [0,0,1] 20 10 Monodomain [1,1,1] 0 0 2 4 6 8 10 12 14 16 18 Nx Figure 6.9: Differences in energies between polydomain, monodomain and non-polar configurations in (3/3) PbTiO3 /SrTiO3 superlattices, as a function of the domain period Nx . Total energies of supercells are divided by Nx × Ny to make them comparable. Circles represent the configurations where the AFD modes are not allowed (Ny = 1), while squares represent configuration with AFD modes condensed (Ny = 2). Diamond indicates a configuration where the domain wall lies along the (1,1,0) direction, also allowing for the condensation of AFD modes. The monodomain phases have been labeled as in Sec. 6.3. In the non-polar configuration, the AFD distortions have been considered. All energies are given with respect to the most stable monodomain configuration. The relative energies of the different polydomain, monodomain and non-polar configurations as a function of the domain periodicity are shown in Fig. 6.9. The most important conclusions that can be drawn are: • The energy of the polydomain structures decreases with the increase of the domain period. The balance between the electrostatic energy (which tends to reduce the domain lateral size), and the domain wall energy density (which tends to increase it) results in an optimum domain periodicity of about 12 unit cells (46.5 Å) (the energy for Nx equal 12 and 16 might be considered as equivalent within the accuracy of our simulations). • For a given domain periodicity, the energy is systematically lowered if rotations of the oxygen octahedra are allowed, with reductions ranging between 22 meV per 30 atom supercell building block (for Nx = 6) to 12 meV (for Nx = 12). This fact highlights the importance of the FE-AFD coupling in these heterostructures, as already discussed in previous section. 166 Chapter 6. PbTiO3 /SrTiO3 superlattices • The effect of the domain wall orientation is small: a change in the orientation of the domain wall from [100] to [110] does not affect significantly the energy of the superlattice, pointing to a rather isotropic domain wall structure, with the energy of the domains depending very weakly on the stripe orientation, in good agreement with experimental results [199], phenomenological Landau-GinzburgDevonshire theory [173], and model Hamiltonian [62] simulations. • Finally, the most stable phase found in our simulations correspond to a monodomain structure, with the polarization in the PbTiO3 layer pointing close to the unit cell diagonal of the perovskite unit cell (configuration labeled as [111] in previous section and Fig. 6.9). Nevertheless the differences in energies between the monodomain and the most stable polydomain configuration are not very large (of the order of 9 meV/30-atom-supercell), suggesting a close competition between them and a strong dependence of their relative stability with, for instance, the electrostatic boundary conditions or the chemical environment during growth process. This energy differences mean that, in practice, at room temperature these two possible configurations are degenerated. Under the light of our results, it sounds plausible that, under certain conditions, the system could be stabilized in a metastable domain structure, specially if one takes into account that due to the finite thickness of actual samples, they might suffer from a depolarizaing effect that would favor domain formation. These considerations would explain why both configurations have been observed experimentally [188]. Figure 6.10 shows the most stable polydomain configuration found for a (3/3) superlattice with Nx = 12 and Ny = 2 (similar patterns are obtained for other domain sizes). The pattern of polarization clearly displays the typical vortices of the closure domain configurations, where the polarization rotates continuously forming a closed flux structure connecting two 180◦ domains. The domain walls are one unit cell thick, as already suggested by first-principles simulations on bulk PbTiO3 [61] and nanocapacitors (see Chapter 5 and Refs. [55] and [46]). As it was already observed in the PbTiO3 /SrRuO3 ferroelectric capacitors, the closing of polarization flux in PbTiO3 /SrTiO3 superlattices is due to large in-plane displacement of the Pb atoms at the PbO layers in the vicinity of the interface. This behavior contrast with that of Ba-based heterostructures, were the rotation of the polarization in BaTiO3 is much more costly. In-plane displacements of Pb are of the order of 0.2 Å, large enough to be visible in a high-resolution transmission electron microscopy (HRTEM) image. However, the experimental observation of the domains of closure in these superlattices remains to be done. Within this vortex configuration, there is no need anymore to keep constant the normal component of the polarization at the interface, since the electric fields that arise from its discontinuity is efficiently screened by the domain structure. This reflects in the out-of-plane polarization obtained at the center of the domains, reaching values in the PbTiO3 layer between 50 and 60 µC/cm2 , depending on the domain periodicity. In some cases we observe that the symmetry lowering due to the AFD distortions allows for the development of a component of the polarization along y. The values for the different 6.4. Polydomain structures 167 Figure 6.10: Polydomain structure of a PbTiO3 /SrTiO3 superlattice showing the pattern of a domain of closure. Balls, representing atoms, are located at the positions of the relaxed structure. The arrows represent local polarization around A atoms (either Pb or Sr) calculated by means of Born effective charges and atomic displacements.. Dotted lines indicate the position of the domain wall. components of the polarization at the center of each domain, inferred from the bulk Born effective charges and the local atomic displacements, are summarized in Table 6.3. For the calculation of values in Table 6.3 a layer by layer polarization is first computed for a unit cell surrounding each cation, and then an average is performed for all the unit cells within the PbTiO3 and SrTiO3 layers. The layer-by-layer polarization of Fig. 6.11(b) shows convergence to an homogeneous well defined value (around 30 µC/cm2 ) within SrTiO3 . On the other hand, at the center of the PbTiO3 layer a progressive reduction is observed upon approaching the interface. This behavior is in good agreement with the t2g -eg splitting experimentally measured by using electron energy loss spectroscopy [199]. Competition between FE and AFD modes is also manifested in polydomain phases. Under the same mechanical boundary conditions, oxygen octahedra rotations and tiltings in the PbTiO3 layer in polydomain structures, where out of plane polarization (50-60 µC/cm2 ) is much larger than in monodomain configurations (30 µC/cm2 ), are smaller than in monodomain phases. Rotations, displayed in Fig. 6.11(c) for a section in the middle of a domain, become approximately one half in polydomain than those in monodomain superlattices (around 2◦ the former and 4◦ in the latter), while tilting angles in polydomain phases are indeed almost negligible. The rotations around the z-axis display the same behavior as in the ground state monodomain case, with an enhancement at 168 Chapter 6. PbTiO3 /SrTiO3 superlattices Figure 6.11: (a) Schematic representation of the center of a domain in a (3/3) PbTiO3 /SrTiO3 superlattice (see region embodied in a dashed box in Fig. 6.10). Color scheme is the same as in Fig. 6.10. (b) Layer by layer polarization inferred from the Born effective charges and the atomic displacements. Each point corresponds to the layer at the same height in panel (a). (c) Amplitude of the rotations (squares) and tiltings (diamonds) of each TiO6 octahedra. the P+ interface due to the covalent bonding between Pb and O, in agreement with the mechanism described in Sec. 6.3.3. Another interesting feature of the polydomain structure is the distortion induced by the opposite shift of up and down domains in the PbTiO3 layer, described in Fig. 6.12. The offset between 180◦ domains was already predicted from first-principles calculations to occur in bulk PbTiO3 [61]. The offset of the Pb sublattice in bulk was found to amount 0.6 Å. In the case of domains in superlattices, the relative shift is about on half of the bulk value, 0.32 Å, for the domain structures with Nx = 12 and 16. In bulk, the distortion of the unit cell induced by the offset between domains with opposite polarization decay rapidly, and the PbTiO3 unit cells recover the mondomain bulk-like shape just two unit cells away from the domain wall. On the contrary, inside the PbTiO3 layer of the superlattices the small distance between domain walls (6 to 8 unit cells) prevents the relaxation to an homogeneously strained region. This induces an inhomogeneous distortion of the unit cells in the PbTiO3 layer, as schematically depicted in Fig. 6.12(b). The effect of this distortion can be quantified by the change in the inplane lattice constant at the center of a domain, when going from the top to the bottom interface of the PbTiO3 layer. This difference, shown in Fig. 6.12(b) amounts a sizable 169 6.4. Polydomain structures Table 6.3: Components of the polarization along y and z direction at the center of the domains (see dashed box in Fig. 6.10) in (3/3) PbTiO3 /SrTiO3 superlattices for different domain sizes. Polarization in µC/cm2 . Nx 6 6 12 12 Ny 1 2 1 2 PyPTO 0 25 0 0 (a) PzPTO 68 56 62 55 (b) 3.87 Å 3.91 Å 3.85 Å 4.00 Å 3.91 Å 4.00 Å 4.00 Å 3.91 Å 4.00 Å 3.85 Å 3.91 Å 3.87 Å PxSTO 0 1 0 0 PzSTO 25 23 32 30 3.92 Å 0.32 Å 3.81 Å Figure 6.12: Elastic distortion induced by the domain structure in PbTiO3 /SrTiO3 superlattices. (a) Inter-layer distance at the center of the domains for a periodicity of Nx = 12 (only half of each domain is shown), here balls representing atoms are located at their positions in a reference paraelectric structure and arrows represent displacements of the cations in the relaxed configuration with respect to that phase. (b) Schematic picture of the distortion where the relative shift of up and down domains is indicated together with the change in the in-plane lattice constant across the PbTiO3 layer. value of 0.1 Å. Notice that, as a consequence of the periodic boundary conditions, domains are aligned along the [001] direction and, while the inhomogeneous in-plain strain is forced to be of opposite sign in the SrTiO3 layer, the offset could, in principle, propagate across the SrTiO3 layer. Instead, despite the very small periodicity of the simulated supercell, we find the “wiggle” induced by the domains to propagate little into the SrTiO3 layer, with the offset being “absorbed” mostly by the interfaces. As a consequence of this, very different interfacial inter-layer distance at P + (3.85 Å) and P − (4.00 Å) interfaces of each domain are observed. For comparison, the interfacial inter-layer distances in the 170 Chapter 6. PbTiO3 /SrTiO3 superlattices monodomain configuration for the (3/3) periodicity are found to be 3.91 Å and 3.92 Å at P + and P + interfaces respectively. As a result the offset of the Sr sublattice is 0.16 Å, significantly smaller than that of the Pb sublattice. Interestingly, the distortion displayed in Fig. 6.12(b) resembles the kind of deformation associated to the flexoelectric effect [200, 201]. This phenomenon consist in an inhomogeneous deformation of a material under applied electric field, or conversely, a polarization of a sample under inhomogeneous strain. This effect has been suggested as a possible mechanism to enhance piezoelectric properties or even induce piezoelectricity in non-piezoelectric materials through strain engineering [34, 202, 30], and is known to be particularly strong in ferroelectrics [203, 204]. In the case of domain structures in these superlattices, this result suggest that the coupling between polarization and strain gradients through the flexoelectric effect might be strong and could be playing a significant role in the elastic coupling of domain structures in thin films. Investigating flexoelectric effects from first principles is hindered by the used periodic boundary condition that limit the number of tensor components that can be calculated [36], but results of this work should encourage further studies on this subject. 6.5 Conclusions Our first-principles simulations show how the FE-AFD-strain coupling in PTO/STO superlattices produces a phase diagram much richer than initially envisaged. The driving force of the coupling is a combination of electrostatic and covalent effects triggered by the symmetry reduction at the interface. In monodomain PTO/STO superlattices we report a new phase (r-phase), with the polarization lying along the [111] direction, for strain values around that corresponding to a SrTiO3 substrate. The new phases might contribute to the stabilization of the monodomain phases over the recently observed and competing polydomain structures [188]. The experimental observation of the in-plane component of the polarization in the superlattices remains to be confirmed. The studied ferroelectric-AFD-strain couplings are not restricted to PTO/STO, and are a promising way of generate novel magnetoelectric couplings in interfaces involving magnetic materials [185]. We have also proved how the formation of domains in short-period PbTiO3 /SrTiO3 superlattices might compete in energy with monodomain configurations. The domains are rather isotropic and display a domain of closure shape, similar to the one theoretically predicted in ferroelectric nanocapacitors and recently observed in various ferroelectric ultrathin films. The formation of domains help to screen the electrostatic energy arising from the polarization discontinuity at the PbTiO3 /SrTiO3 interface. Both the homogeneous out-of-plane polarization of SrTiO3 and the evolution of the layer by layer polarization of PbTiO3 at the center of each domain are in good agreement with the t2g -eg splitting inferred from electron energy loss spectroscopy with unit cell resolution. Our results suggest that by controlling the superlattice periodicity, the monodomainpolydomain phase transition could be engineered to give a broad spectrum of enhanced functional properties. Conclusions As it has been discussed extensively throughout this thesis, perovskite oxide thin films offer a fantastic possibility for the design of multifunctional systems. One particular issue of great importance for the performance of such devices are the electrostatic boundary conditions, which can dramatically affect the structural and electronic properties of the materials. The first principles study of the screening properties in perovskite oxide thin films, has been precisely the leitmotif of our work throughout these years. We have pointed out several times throughout this report that, in the field of complex oxide thin films, the degree of development of first principles simulations and experimental techniques have advanced to the extent that both theorist and experimentalist can investigate essentially the same kind of systems. In this context, the role of first-principles calculations is two-folded: it constitutes a tool that allows us to explore material combinations and configurations even before they are grown or detected in the laboratory, and to complement the experimental results providing physical interpretations, helping to optimize the functionalities of the systems. A very important fraction of our work in the last years has been devoted to the study of the applicability limits of the most common first-principles approach for the study of oxides thin films, namely the DFT and more particularly, the LDA and GGA approximations. These methods have provided in the last years invaluable insights on the properties of these materials but have some limitations. As more and more complex systems are being studied from first principles, issues derived from the misuse of these approximations have started to arise. We have made an important effort to provide a comprehensive, but at the same time clear and self-contained, guide aiming to clarify the limitations of this theoretical method. We have tried to point out the typical fingerprints of unphysical results which are a consequence of those limitations, focusing in a particularly relevant kind of systems: the ferroelectric capacitors. These limitation are specially important for the study of the electronic structure. This does not mean that they affect exclusively the electronic structure, as we have seen the pathological description of the electronic properties have dramatic consequences on the structural properties of the system, which is something that has been systematically overlooked in the past. Some of the pathological charge transfers that we have attributed to a wrong description of the electronic structure by the LDA or GGA methods have been sometimes identify with metal-induced gap states (MIGS). In Chapter 3 we already suggest some 171 172 Conclusions tools to clearly distinguish these physically meaningful and relevant charge transfers and the pathological ones. Chapter 4 is entirely devoted to the characterization of the evanescent states in ferroelectric capacitors. Though this is still a work in progress here we tried to put in context many properties associated to MIGS that are often discussed in the literature, but which connection is rarely explicitly treated. These states, are propagating states in the metallic side of a metal/insulator junction and have energies within the band gap of the latter. As an electron encountering a finite potential barrier, this states penetrate in the insulator and decay exponentially. We have seen that the charge rearrangements associated to the MIGS play an important role in the properties of capacitors, particularly in the band alignment. Properties of these states can be connected to the characteristics of the complex band structure of the bulk insulator but, as has been discussed in Chapter 4, interface intrinsic properties ultimately determine their spatial an energetic distribution. This stresses out the importance of an explicit treatment of the actual interface, taking into account details with atomic resolution which are very relevant for thin-film devices. Chapters 3 and 4, which are mainly devoted to properties of ferroelectric capacitors related with their electronic structure, highlight the importance of moving towards improved functionals. LDA and GGA approximations showed to be sufficient to achieve a good description of structural properties in oxide thin films, but the discovery of new functionalities and couplings between structural and electronic properties demands taking a step forward and start working with more accurate methods. GW method constitutes a precise alternative for the research of the electronic structure, and has the advantage of being developed on top of DFT. Although it is true that these methods provide very accurate description of the electronic structure of materials, they are still too computationally-expensive to be applicable in realistic complex systems like those studied in this report. Hybrid functionals, on the other hand, provide a very promising way to improve the current knowledge of the physics of oxide thin films. “Traditional” hybrid functionals, like B3LYP or B1, were developed in the context of quantum chemistry and have been shown to provide accurate description of the atomization energies, bond lengths, and vibrational frequencies, together with good energy spectra for most molecules. However when applied to some solids, and to ferroelectrics in particular, they were found to fail to reproduce the correct structural properties of the materials. Fortunately, there have been important advances in this direction. Specifically, the development of the B1-WC functional (a mix of exact exchange with the Wu-Cohen GGA functional that has shown an exceptional description of the atomic structure of oxide perovskites) opens the door to the study of many phenomena in complex oxide systems that were completely beyond the scope of the most common approximations used today. The use of a hybrid functional is, of course, much more computationally demanding than LDA or GGA, but given the the fast evolution of computer science (both on the software and hardware fronts) we should expect them to become the “standard” calculation relatively soon. And today, given the limitations of common DFT approaches discussed in this thesis, a careful choice of the systems to be simulated can already provide enormous amounts of information. 173 We have also investigated polarization domains in ferroelectric thin films, both in capacitors and in superlattices. In both kind of systems, we have observed formation of closure domains, a structure that was thought unlikely to form in ferroelectric materials due to the associated elastic energy. At odds with this common assumption, first principles and model Hamiltonian simulations predicted the formation of domains of closure in a several different systems, from BaTiO3 /SrRuO3 capacitors (as reported in Chapter 5) to PbTiO3 free standing slabs. Theoretical studies have found this domain wall structure to be surprisingly robust with respect to the ferroelectric material, the level of screening provided by electrodes (if they exist), and the theoretical approach. Very recently, the development of subatomic-resolution transmission electron microscopy have finally allowed the experimental observation of such structures, confirming the theoretical predictions proposed just a few years before. This is one beautiful example of the level of predictability that first-principles simulations have achieved in the last years. Now that details about the precise structure of domain walls in ultra-thin films are being determined, it is time to analyze other associated properties. For instance, very recently, conductivity has been observed in domain walls in ferroelectric thin films. It was first observed in BiFeO3 thin films and attributed to a reduction of the band gap at the BiFeO3 domain walls, but the predicted change in the electronic structure at the studied domain walls was too small to account for such a conductivity. It has also been suggested that head-to-head or tail-to-tail domain walls and the associated electric fields could explain the conductivity, but then, conductivity was observed in tetragonal PZT as well, where spontaneous formation of polar domain walls is more unlikely. The most reasonable explanation is, to our understanding, the pinning of domain walls at vacancies sites, something that has already been studied from first principles in bulk PbTiO3 . The migration of vacancies to domain walls and the pinning of the latter suggest a relatively large concentration of defects at those regions of the material. The large electric fields that we have found at the boundaries between domains of closure reinforces this hypothesis. The deep understanding of properties of domain boundaries beyond their structure could help to optimize some of these functionalities and lead to a potential use of domains walls as active pieces in ultra-thin films devices. This would open new avenues for the development of new multifunctional materials, where both the bulk-like and domain-wall properties could be exploited. The investigation from first-principles of such functionalities would, again, benefit from the use of improved functional that provide a better description of the electronic structure of the system. The number of possible functionalities that can be engineered in superlattices grows every day. There is a great number of different materials, with similar structures but completely different properties, that can be combined in the laboratory with atomic control on the interface quality, giving rise to unimaginable properties. We have seen how new couplings and phases emerge as a consequence of the interfacial effects in superlattices, properties that can be exploited to design synthetic functional materials. The breaking of the system in domains of polarization increases complexity to the problem. Our simulations have show that, even thought the domain structure provide a very effective screening, for small periodicities there is an electrostatic coupling between 174 Conclusions the PbTiO3 layers, which shows up through the polarization of the SrTiO3 in between. The energy penalty due to the polarization of the SrTiO3 suggest that the electrostatic coupling should weaken as the staking periodicity increases. However, superimposed to the electrostatic effect we have observed an inhomogeneous strain field associated to the polydomain structure that might enhance the coupling between the ferroelectric layers. To our knowledge, this mechanism of elastic coupling has never been discussed and could be crucial in the determination of the domain structure in superlattices. We plan to perform simulations on polydomain superlattices with increasing periodicity aiming to observe a transition from electrostatically-coupled to elastically-coupled ferroelectric layers. In this context, not only new combinations of materials should be explored, but also new geometries that might optimize a given particular property. The stability of vortex structures in ferroelectric nanostructures, for instance, can be used to design nanoparticles able to sustain a toroidal moment or chiral nanorods with switchable optical activity. Some of these systems are still beyond the possibilities of current experimental techniques, and of course, some experimental devices are still too complicated to be simulated fully from first-principles. Therefore, the feedback with model Hamiltonian simulations is fundamental, bridging the size and energy scale between first principles simulations and experiments. Fortunately, the collaboration between theoretical and experimental groups in this field is very close, providing an extremely motivating work environment. This definitely translate into more effective interactions and fruitful projects, which constitutes one of keys reasons for the fast development that this field has experienced in the last years. Appendix A Ocupation function and energy smearing of the local density of states The following analysis is entirely due to M. Stengel. We include it here because it came up after discussions during the research reported Chapter 3 and because it is critical for the understanding of some key points of that work. We aknowledge M. Stengel the permission to reproduce it here. A.1 Convolutions Convolution is a mathematical operation on two functions f and g, producing a third function that is typically viewed as a modified version of one of the original functions. For the purpose of the present notes, it is useful to think of f as a data curve containing the relevant physical information, and g as a rapidly-decaying “smoothing” function that produces a local weighted average of f . We define the convolution of f and g, f ∗ g, as the following integral transform, (f ∗ g)(x) = Z +∞ −∞ f (y)g(x − y)dy (A.1) Convolutions have many properties, including commutativity and associativity. Furthermore, the Dirac delta can be thought as the identity under the convoluton operation, (f ∗ δ)(x) = f (x), (A.2) and under certain assumptions an inverse operation can also be defined. In other words, the set of invertible distributions forms an abelian group under the convolution. A particularly useful property holds in relationship to the Fourier transform, F(f ∗ g) = k · F(f ) · F(g) 175 (A.3) 176 Appendix B. Ocupation function and energy smearing of the LDOS where F(f ) denotes the Fourier transform of f , and k is a constant that depends on the normalization convention for the Fourier transform. Thus, in reciprocal space the convolution becomes a simple product. This naturally provides an efficient convolution algorithm: the workload is reduced from O(N 2 ) to O[N log(N )]. A.2 Local density of states In this work we use [Eq. (3.27)] the following formula to compute the smeared local density of states (LDOS), X ρ̃(r, E) = wk |ψnk (r)|2 g(E − Enk ). (A.4) nk We shall see that this is indeed a convolution. We first get rid of the spatial cordinates. To this end, it is customary to integrate the LDOS in real space over a given volume V , X ρV (E) = wk ρnk (V )g(E − Enk ), (A.5) nk where Z ρnk (V ) = V d3 r |ψnk (r)|2 . (A.6) (Note that sometimes it might be more convenient to use a projected density of states, rather than a local density of states. In such cases it is sufficient to replace the realspace integral in the above equation with an appropriate sum over angular momentum components. The following discussion remains unchanged.) Now the LDOS is a function of a single energy variable. If we write X fV (E) = wk ρnk (V )δ(E − Enk ), (A.7) nk we can easily see that ρV = fV ∗g. This leads to a simple reciprocal-space expression. We first define an energy window, [Elow , Ehigh ], that contains the entire eigenvalue spectrum Enk . We actually take a window which is slightly larger, where this “slightly” depends on the decay properties of g, Elow = min(Enk ) − , Ehigh = max(Enk ) + . (A.8) The width of this window is Ehigh − Elow = ∆E. We represent ρV (E) in reciprocal space as a discrete Fourier transform, X ρV (E) = eiωE ρV (ω), (A.9) ω where ω = 2πn/∆E and n is an integer. By using Eq. (A.3) we have ρV (ω) = ∆E · fV (ω) · g(ω). (A.10) 177 A.3. Gaussian vs. Fermi-Dirac smearing a 1 c 0.5 fG(E) fFD(E) 0.4 0.3 0.2 0.1 0 -0.5 0 0 -30 0.5 4 -20 -10 0 10 20 30 0.05 b gG(E) gFD(E) 3 d 0.04 gG(ω) gFD(ω) 0.03 2 0.02 1 0.01 0 0 -0.5 0 Energy (eV) 0 0.5 10 20 30 40 -1 Frequency (eV ) 50 Figure A.1: (a) Gaussian (σ = 0.15 eV) and Fermi-Dirac (σ = 0.075 eV) occupation functions. (b) Kernel of the occupation functions as defined in the text. (c-d) Fourier transform of the smearing kernels g, assuming an energy window of [−1, 1]. The Fourier transform of a Dirac delta centered in the origin is a constant. Eq. (A.10) then decomposes the local density of states into a structure factor, fV (ω) = 1 X wk ρnk (V )e−iωEnk , ∆E (A.11) nk and a form factor g(ω). Obviously, this formulation is only convenient if the function g has a fast decay in both real and reciprocal space, so that the sum in Eq. (A.9) can be truncated. This is indeed the case for the most widely used smoothing functions g, as we shall see in the following. A.3 Gaussian vs. Fermi-Dirac smearing The Gaussian smearing (G) and the Fermi-Dirac (FD) smearing are by far the most popular choices for the occupation function in first-principles calculations of metallic systems. If we define the occupation function f as the integral of a “kernel” function g, f (E) = 1 − Z E g(x)dx, −∞ (A.12) 178 Appendix B. Ocupation function and energy smearing of the LDOS one can verify that the Gaussian or Fermi-Dirac occupation are, respectively, reproduced by the following choices of g, gG (x) = gFD (x) = 1 2 2 √ e−x /σ , πσ σ −1 , 2 + ex/σ + e−x/σ (A.13) (A.14) where σ is the smearing energy [these correspond to Eq. (3.28a) and Eq. (3.28b)]. It is easy to see that, by combining Eq. (A.13) or Eq. (A.14) with Eq. (A.12) one obtains the standard definitions of the occupation function (we assume that the complementary error function, erfc, values 2 at −∞), fG (x) = fFD (x) 1 2 erfc (x/σ), = 1 ex/σ +1 . (A.15) (A.16) It is useful to spell out the explicit formulas for the Fourier transforms of both smearing functions, 2 2 gG (ω) = gFD (ω) = e−ω σ /4 , ∆E πωσ . ∆E sinh(πωσ) (A.17) (A.18) Note that the above formulas are normalized according to the conventions on the Fourier transforms that we used in the previous section. The functions f and g defined above are shown in Fig. A.1. Note that a different choice of σ was used in the Fermi-Dirac and in the Gaussian case. A FD distribution is roughly equivalent to a G distribution with a σ value that is twice as large. In the main text and here we have assumed that it is a good idea to use the same g kernel in the calculation and in the construction of the LDOS. We shall substantiate this point in the following Section. A.4 On the optimal choice of g In many cases, the specific choice of the g function to be used in Eq. (A.4) is largely arbitrary. Typically, the goal is to filter out the unphysical wiggles due to the discretization of the k-mesh, but at the same time to preserve the main physical features, without blurring them out completely. This calls for a smearing function that is neither too sharp nor too broad. Since a “slightly too broad” or a “slightly too sharp” smearing function usually does not influence the physical conclusions, in many cases one has the freedom of choosing whatever yields the clearest visual aid to support the discussion. There are cases, however, where this choice is not just a matter of aesthetics, and using the “wrong” g function can qualitatively and quantitatively influence the interpretation of the results. More specifically, the issue concerns cases where the analysis of the 179 A.4. On the optimal choice of g 4 1 0.8 3 0.6 2 0.4 1 0.2 0 -1 -0.5 0 0.5 Energy (eV) 1 0 -1 -0.5 0 0.5 Energy (eV) 1 Figure A.2: Left: Fermi-Dirac occupation function, identical to that of Fig. A.1(a) (solid curve); hypothetical orbital located at an energy of 0.15 eV above the Fermi level (dashed line); the thermal occupation of this state yields a total charge of 0.119 electrons (red dot). Right: density of states corresponding to the single isolated orbital at an energy of 0.15 eV above the Fermi level, smeared by using the gFD kernel of Fig. A.1(b); the integral of the DOS up to the Fermi level (shaded area) yields the exact same charge of 0.119 electrons. LDOS (or DOS or PDOS) is used to detect and quantify the population of orbitals that lie close in energy to the Fermi level. As we focus on charge spill-out phenomena that concern the conduction band of a dielectric/ferroelectric film in contact with a metallic electrode, this is a central point of our work. The problem is most easily appreciated by looking at the left panel of Fig. A.2. There is a single orbital lying at an energy of 0.15 eV above the Fermi level. As this orbital lies above the Fermi level, one might be tempted to think that the orbital is empty, and that charge spill-out does not occur at all. However, calculations in metallic systems are routinely performed by using an occupation function that is artificially broadened, in order to improve convergence of the ground-state properties; in Fig. A.2 we assume a Fermi-Dirac occupation with a fictitious electronic temperature of 0.075 eV. It is easy to see that with such an occupation function, the orbital lying at 0.15 eV won’t be empty, but will be “thermally” populated by tail of the Fermi-Dirac distribution. The final result is a charge transfer of 0.119 electrons into this orbital. Now, is there a “right” way to construct the DOS curve, such that the abovementioned charge transfer could be qualitatively and quantitatively inferred from the DOS, without knowing any further detail of the calculation? The answer is yes, and consists in constructing the DOS by using a broadening g function which is consistent with the occupation function used by the code. In this case, this is gFD , with a σ identical to that used to calculate the electronic ground state. To demonstrate this point, we plot in the right panel of Fig. A.2 the DOS of this isolated orbital at 0.15 eV, appropriately convoluted with gFD . Eq. (A.12) guarantees that, by doing this, one recovers the very intuitive result that the total amount of electron charge, Q, present in the volume V (over which the LDOS was integrated) exactly corresponds to the integral of the DOS 180 Appendix B. Ocupation function and energy smearing of the LDOS up to the Fermi level, Z EF Q= ρV (E)dE. (A.19) −∞ Then, a simple look at the DOS curve is sufficient to ascertain whether a significant transfer of charge has occurred into a specific group of bands. As this rigorous sum rule can be very practical in the analysis of the results, we encourage a systematic use of the “internally consistent” LDOS construction described above. Appendix B Local polarization via Born effective charges In this Appendix we include a discussion due to M. Stengel about the approach, used in several parts in this manuscript and ubiquitously in the recent literature, of associating the local value of the “effective” polarization (i.e. the induced P with respect to the reference centrosymmetric configuration [132]) in capacitor heterostructures with an approximate formula, based on the Born effective charges, Z ∗ . In particular, M. Stengel [105] provide formal justification for an improved formula, still based on the Z ∗ , that we introduced in Sec. 3.3.2 [Eq. (3.38)]. We aknowledge M. Stengel the permision to reproduce here the discussion. Recall the definition of the approximate effective polarization in terms of the Born effective charges in a bulk solid, PZ = e X ∗ Z Rαz . Ω α α (B.1) It is easy to verify that the layer-resolved expression PjZ of Eq. (3.37) reduces to P Z in the case of a periodic crystal, where PjZ is a constant function of the layer index j. P Z does not reduce to the “correct” polarization P (D) at any value of D, as it does not take into account the additional polarization of the electronic cloud due to the internal field E(D) (recall that the Born effective charges are defined under the condition of zero macroscopic electric field. [14]) Taking the Taylor expansion of the polarization as a function of D (we assume for simplicity that D, P and P Z all vanish in the reference centrosymmetric structure), we can write P Z (D) = dP Z dP Z dE D + ... = D + ... dD dE dD (B.2) For small values of D, we can truncate the previous expansion at the linear order term. Now, by definition 181 182 Appendix B. Ocupation function and energy smearing of the LDOS Table B.1: Values of the susceptibilities χ and scaling factors χTOT /χION for the ferroelectric materials considered in Chapter 3. BaTiO3 PbTiO3 KNbO3 where χION TOT -48.87 -96.54 -34.92 ∞ 6.48 8.33 6.27 χTOT /χION 0.90 0.93 0.87 dP Z = χION , dE is the lattice-mediated susceptibility, and (B.3) dE = (0 TOT )−1 , (B.4) dD where TOT is the total dielectric constant of the insulator (relative to the vacuum permittivity 0 ). Substituting Eq. (B.3) and Eq. (B.4) into Eq. (B.2) P Z (D) ∼ D χION . 0 TOT (B.5) The same kind of arguments applied to the total polarization yield P (D) ∼ D χTOT , 0 TOT (B.6) where χTOT is the sum of the lattice-mediated susceptibility, χION , and the purely electronic (frozen-ion) susceptibility, χ∞ . Note that χION is not bound to be positive. In a ferroelectric material, for example, the centrosymmetric reference structure is unstable and therefore yields a negative χION (and hence TOT ), as discussed in Ref. [51]. The present derivation is general and encompasses those cases. From the above considerations it immediately follows that an estimate of the total polarization, which is exact in the linear limit, can be given as P (D) ∼ χTOT Z P (D). χION (B.7) This is essentially Eq. (3.38). In practice, χION and χ∞ are calculated in the reference phase according to the standard definitions, [205] χION = 0 (TOT − ∞ ) = ∗ )2 0 e2 X (Z̃m , 2 M0 Ω m ωm (B.8) ∗ are the normal mode charges and ω 2 are the eigenvalues where M0 is a unit mass, Z̃m m of the dynamical matrix, and 183 0.8 1.5 PbTiO3 (bulk) 2 Polarization (C/m ) 0.6 2 Polarization (C/m ) BaTiO3 (film) 0.4 0.2 1 0.5 * Bare Z Berry phase Rescaled Z 0 0 0 0.1 0.2 0.3 0.4 0.5 0 0.2 0.4 0.6 0.8 Reduced electric displacement d * 1 Figure B.1: Polarization P in a BaTiO3 film and PbTiO3 bulk as a function of the reduced electric displacement field d = DS. Data are taken from Ref. [52] (see Section III.C.1) and Ref. [51]. χ∞ = 0 (∞ − 1), −1 ∞ = 0 dE . dD fixed−ions (B.9) The values of these physical constants that are relevant for the results presented in this manuscript are reported in Table B.1. We proceed in the following to test this approximation on two representative bulk ferroelectric materials, PbTiO3 and BaTiO3 . We take the relevant data (linear susceptibilities, Born charges and relaxed structures as a function of D) from the calculations of Ref. [51] and Ref. [52]. Note that the BaTiO3 calculation was performed at a fixed value of the in-plane lattice parameter (indicated as “film” in the figure) while in the PbTiO3 calculation both a and c parameters were relaxed for each value of D. The results are presented in Fig. B.1. In both cases, the “bare” value P Z is systematically overestimated compared to the Berry-phase polarization. With the correction described above, i.e. by rescaling all values by the factor χTOT /χION , the approximate value of P accurately matches the Berry-phase one. The accuracy is surprisingly good in BaTiO3 , where the maximum deviation is of the order of 1%. In PbTiO3 , for large values of d the rescaled-Z ∗ value of P presents significant deviations. Note that these deviations mostly concern values of d that are larger than that of the ferroelectric ground state (d ∼ 0.74), and therefore are not of concern in this manuscript. We ascribe these deviations to the field-induced structural transition that was described in Ref. [51]. In conclusion, this simple rescaling factor appears to be an effective way to obtain 184 Appendix B. Ocupation function and energy smearing of the LDOS a relatively accurate value of the local P in heterostructure calculations, based only on the local atomic positions and a few ingredients that can be easily computed in the bulk reference structure. From the results of our tests, we expect the agreement to be best in cases where the polarization is small (closer to the linear limit where the approximation becomes exact). Furthermore, cases where the ferroelectric polarization can be represented in terms of a single “soft mode” such as BaTiO3 seem to work better than cases, like PbTiO3 , where significant mode mixing and non-trivial structural transitions occur at higher D values. Appendix C Complex band structure within the nearly-free electron model Given its periodicity, the potential in the insulator can be expressed as a Fourier series. If, for the sake of simplicity, we restricting the Fourier expansion to the first term (besides the Gamma term which is a constant) we get a potential in the insulator V (z) = V0 + Vg cos(gz), (C.1) where g = 2π/a is the shortest reciprocal lattice vector. Within the nearly-free electron model, at the Brillouin zone boundaries, the perturbative potential mixes eigenstates from different bands. At the Brillouin zone boundaries the eigenfunctions are thus a mixing of two plane waves (which are the eigenfunctions of the unperturbed system) ψIk (z) = Aeikz + Bei(k−g)z . (C.2) Inserting previous trial function into the time-independent Schrödinger equation − d2 + V (z) ψI = EψI , dz 2 (C.3) we get 2 k + V0 + Vg cos(gz) − E Aeikz + (k − g)2 + V0 + Vg cos(gz) − E Bei(k−g)z = 0, (C.4) which must be satisfied at every point in space. Evaluating in z = 0 and z = a/2 we get, respectively 2 k + V0 + Vg − E A + (k − g)2 + V0 + Vg − E B = 0, 2 k + V0 − Vg − E A − (k − g)2 + V0 − Vg − E B = 0. 185 (C.5a) (C.5b) 186 Appendix C. Complex band structure within the nearly-free electron model Adding and subtracting previous equations, and writing in matrix form, they transform into 2 k + V0 − E Vg A = 0. (C.6) Vg (k − g)2 + V0 − E B Previous system of equations can be more easily solved using a new variable κ = k − g/2, which is the deviation of k from the Brillouin zone boundary. Equation C.6 transforms into (κ + g/2)2 + V0 − E Vg A = 0. (C.7) Vg (κ − g/2)2 + V0 − E B Eigenvalues of the Schrödinger equation for the system are obtained finding the energy values E that makes 0 the determinant of previous matrix equation (κ + g/2)2 + V0 − E Vg = 0, 2 Vg (κ − g/2) + V0 − E 2 κ + κg + (g/2)2 + V0 − E Vg Vg κ2 − κg + (g/2)2 + V0 − E = 0, κ4 − κ2 κg + κ2 (g/2)2 + κ2 V0 − κ2 E +κ2 κg − κ2 g 2 + κg(g/2)2 + κgV0 − κgE +κ2 (g/2)2 − κg(g/2)2 + (g/2)4 + (g/2)2 V0 − (g/2)2 E +κ2 V0 − κgV0 + (g/2)2 V0 + V02 − V0 E −κ2 E + κgE − (g/2)2 E − V0 E + E 2 − Vg2 = 0, κ4 + (g/2)4 + V02 + E 2 + 2κ2 (g/2)2 + 2κ2 V0 − 2κ2 E + 2(g/2)2 V0 − 2(g/2)2 E − 2V0 E − κ2 g 2 − Vg2 = 0, 2 2 κ + (g/2)2 + V0 − E − κ2 g 2 − Vg2 = 0, (C.8) which finally leads to E = κ2 + (g/2)2 + V0 ± κ2 g 2 + Vg2 1/2 . (C.9) Appendix D Resumen La investigación de óxidos de metales de transición se encuentra en un momento crucial. La situación es tan interesante que ha sido comparada con la de la fı́sica de semiconductores de hace sesenta años [1]. Se trata ésta de una comparación muy seria ya que hoy en dı́a nustras vidas dependen enormemente de multitud de dispositivos que han podido desarrollarse gracias a la investigación básica en ciencia de materiales que se realizaba en aquella época. Sin embargo esta comparación no es gratuita. Las última décadas de investigación en óxidos de metales de transición han sido tremendamente excitantes y ha llevado al descubierto un gran número de funcionalidades en estos materiales, como la superconductividad o la magnetoresistencia colosal por citar un par de ejemplos. En los últimos años se ha prestado una particular atención a una familia de óxidos de metales de transición en particular, que comparten una estructura cristalina de tipo perovskita. Bajo la sencillez de esta estructura, con tan solo cinco átomos en la celda unidad para la estructura cúbica de referencia de alta simetrı́a, se esconde un gran número de sutiles propiedades fı́sicas. Estos materiales, a pesar de compartir una estructura atómica muy similar, presentan una amplia gama de propiedades: superconductividad, ferromagnetismo, magnetorresistencia colosal, multiferroicidad, propiedades ópticas no lineales ... Más interesante aún, la amplia gama de propiedades que surgen de estos materiales sugiere que la aparición de una propiedad en particular ha de ser la consecuencia de un delicado equilibrio entre múltiples interacciones que probablemente sean comunes a muchos de los miembros de esta familia de materiales. De hecho, este diagrama de fases tan diverso surge de la estrecha competencia entre las diferentes las interacciones que tienen lugar en estos materiales. Mientras que en otros tipos de materiales tales como semiconductores o algunos metales, alguna de las interacciones involucradas – repulsiones coulombianas, deformaciones, intercambio, etc – domina claramente sobre las otras y determina las propiedades de volumen del sistema, en los óxidos de metales de transición estos efectos son muy a menudo de la misma magnitud. De tal forma que estos materiales suelen presentar una compleja competición de varias fases y una fuerte sensibilidad hacia perturbaciones externas [188, 3]. Esto hace que estos materiales sean los candidatos ideales para el diseño de dispositivos artificiales con funcionalidades a la carta. 187 188 Resumen Una de las propiedades que presentan algunas de estas perovskitas es la ferroelectricidad. Un material ferroeléctrico es un aislante que presenta al menos dos estados diferentes de la polarización e nausencia de campo eléctrico, pudiendose inducir la transición de uno a otro mediante la aplicación de un campo eléctrico externo [4]. El término “ferroeléctrico” fue acuñado en analogı́a a los materiales ferromagnéticos, ya que ambos presentan un ciclo de histéresis cuando la polarización (magnetización en el caso de un material ferromagnético) se mide en función del campo eléctrico (magnético) aplicado. Los ferroeléctricos son materiales con un gran interés aplicado [5, 6]. La ferroelectricidad, es decir, la capacidad de transitar entre dos o más estados de polarización al aplicar un campo externo, puede ser explotada por ejemplo para la fabricación de dispositivos de memoria, donde cada estado de la polarización puede ser asignado a los valores 0 y 1 de un bit de información. ste es el principio básico de funcionamiento de las memorias ferroeléctricas de acceso aleatorio (FeRAM). Además la ferroelectricidad suele estar asociada a otras propiedades de gran interés. Por ejemplo, todos los materiales ferroeléctricos son también piezoeléctricos (la aplicación de un campo eléctrico puede inducir una deformación y viceversa) y piroeléctricos (los cambios de temperatura de la muestra modifican la polarización). Estas propiedades se explotan ya hoy en dı́a en la fabricación de transductores, actuadores o detectores de infrarrojos. Uno de los ejemplos más exitoso son las cerámicas de PbZr1−x Tix O3 que están presentes en gran variedad de dispositivos, desde equipos de ecografı́a hasta los inyectores de los motores de automóvil o los microscopios de fuerza atómica. Además, los materiales ferroeléctricos poseen una constante dieléctrica muy grande que permite su uso para la fabricación de condensadores de memorias dinámicas de acceso aleatorio (DRAM). La constante miniaturización de los dispositivos electrónicos impuesta por la industria electrónica e impulsada por la necesidad de dispositivos electrónicos más rápidos y al mismo tiempo más pequeños y más eficientes energéticamente, ha motivado el estudio de las propiedades de los materiales ferroeléctricos a escala nanométrica. Es bien sabido que las propiedades de volumen los ferroeléctricos y de la mayorı́a de las perovskitas se ven fuertemente afectadas por las condiciones de contorno, que se hacen especialmente relevantes al disminuir el tamaño de los dispositivos. Se sugirió, por ejemplo, que la ferroelectricidad tenı́a un tamaño crı́tico de unos 10 nm, por debajo del cual la alteración en el balance entre las interacciones que gobiernan la ferroelectricidad y la aparición de campos de depolarización, provocarı́an la pérdida de la polarización espontánea. Sin embargo, con los avances en la sı́ntesis y caracterización experimental de láminas ultradelgadas se ha observado ferroelectricidad en pelı́culas cada vez más delgadas, encontrando que el espesor crı́tico para la ferroelectricidad es de tan sólo unas pocas monocapas. Por otro lado, la mejora de las técnicas de crecimiento ha permitido aprovechar el sutil equilibrio entre las diferentes inestabilidades y la fuerte sensibilidad de estos materiales a las condiciones de contorno para modificar a voluntad las propiedades de las láminas delgadas de perovskitas. La búsqueda de una ruta para diseñar y sintetizar materiales artificiales con funcionalidades a la carta ha impulsado enormemente la investigación en estos sistemas. Sin embargo, la estrecha competencia entre las diferentes interacciones 189 y fases hace muy difı́cil, si no imposible, predecir las propiedades de las estructuras artificiales en términos de reglas simples y a partir de las propiedades de volumen de los materiales constituyentes. Ésta es una de las razones por las que las simulaciones desde primeros principios juegan un papel fundamental en las notables avances que el campo ha experimentado en los últimos años [7]. La rápida evolución de los modelos atómicos, impulsada por el rápido y constante aumento de la potencia de cálculo (hardware) y por importantes avances en el desarrollo de algoritmos más eficientes (software), hace posible describir las propiedades de los materiales de forma muy precisa utilizando métodos basados en las leyes fundamentales de la mecánica cuántica y de la electrostática. Incluso si el estudio de sistemas complejos requiere algunas aproximaciones prácticas, estos métodos no emplean ningún parámetro ajustado empı́ricamente. Por ello se les conoce como métodos desde “primeros-principios” o “ab-initio”. La situación actual es particularmente interesante. Por un lado, los recientes avances permiten controlar la sı́ntesis de láminas delgadas a escala atómica y medir localmente sus propiedades ferroeléctricas [8]. Por otro lado, el aumento constante de la potencia de cálculo y las mejoras en la eficiencia de los algoritmos permiten el estudio preciso desde primeros principios de sistemas cada vez más grandes y complejos que coinciden en tamaño con aquéllos crecidos en los laboratorios, lo que permite una retroalimentación continua entre los experimentos y los modelos teóricos. Este esfuerzo conjunto ha llevado, en el último par de décadas, a avances muy significativos en el conocimiento a nivel microscópico de las propiedades ferroeléctricas de las perovskitas y de los compuestos relacionados. Cada paso adelante da lugar al descubrimiento de nuevos fenómenos que no hace más que incrementar el número de interrogantes, genera nuevas oportunidades para la explotación práctica de las funcionalidades y motiva aún más la investigación de estos materiales. Un buen ejemplo es el descubrimiento de interfases conductoras en superredes de LaAlO3 y SrTiO3 , dos materiales aislantes [9], o la conductividad de las paredes de dominio en BiFeO3 [10]. Un aspecto de gran interés debido a sus implicaciones tanto en las propiedades fı́sicas básicas de las láminas delgadas ferroeléctricas como en sus posibles aplicaciones, es la comprensión de los mecanismos de apantallado en dichos sistemas. El valor de la polarización en la superficie de una lámina delgada o su discontinuidad a través de una interfase con un electrodo o con otro material aislante genera una carga que da lugar a un campo de depolarización que tiende a suprimir la polarización. Pueden darse varios mecanismos para compensar estas cargas de polarización: acumulación de carga de apantallado en los electrodos, adsorbentes iónicos en una superficie libre o la ruptura del sistema de dominios en la polarización. En esta tesis se han estudiado algunos de estos mecanismos desde primeros principios. Hemos prestado una especial atención a los aspectos metodológicos relacionados con las propiedades de apantallado en ferroeléctricos que pueden ser importantes para el estudio desde primeros principios de propiedades de interfases. Para ello nos hemos centrado en dos sistemas particularmente importantes: (i) las interfases ferroeléctrico/metal presentes en los condensadores ferroeléctricos y (ii) las interfases ferroeléctrico/ferroeléctrico incipiente tales como las superredes PbTiO3 /SrTiO3 (sistema que está atrayendo un gran interés debido a la aparición de una ferroelectrici- 190 Resumen dad impropia en el lı́mite de pelı́culas ultradelgadas). En el primer caso estudiaremos el reordenamiento de carga en las uniones metal/ferroeléctrico, asociado a la formación de estados evanescentes en el gap, y la formación y las propiedades de los dominios de polarización en este tipo de dispositivos. En el caso de las superredes de PbTiO3 /SrTiO3 , el descubrimiento de un acoplamiento propio de la interfase entre inestabilidades polares y no polares, que no se da en los materiales en volumen, ha atraı́do mucha atención en los últimos años. En estos sistemas exploramos cómo varı́a el diagrama de fases con la deformación epitaxial, su efecto sobre el acoplamiento entre las inestabilidades y las propiedades de las fases polidominio. Esta memoria se encuentra organizada de la siguiente forma. En el Capı́tulo 1 se introducen las propiedades generales de los materiales ferroeléctricos ABO3 , se discuten las distintas inestabilidades presentes en estos compuestos, su competición y la conexión con la aparición de la ferroelectricidad. Estudiamos cómo los efectos del tamaño y las condiciones de contorno afectan a estas propiedades, y cómo esto puede utilizarse en la obtención de estructuras con nuevas funcionalidades. En este capı́tulo se presta una especial atención a las condiciones de contorno electrostático y a los distintos mecanismos de apantallado que pueden tener lugar en una lámina ferroeléctrica delgada, siendo éste el tema principal de este trabajo de tesis. En el capı́tulo 2 se describen los detalles teóricos básicos de los métodos de primeros principios utilizados para llevar a cabo la investigación que se presenta en esta memoria. Algunas problemas asociados con la simulación de heteroestructuras se tratan en el capı́tulo 3. Ofreceremos un procedimiento claro para detectar resultados patológicos como consecuencia de un mal uso del método teórico más empleado, la teorı́a funcional de la densidad (DFT), y sugeriremos mecanismos para evitar tales errores. Los resultados de este capı́tulo no son tan solo metodológicos, ya que algunos mecanismos de apantallado que han sido detectados en heteroestructuras patológicas pueden ser relevantes para algunas interfases reales. El capı́tulo 4 se centra en estudio de los estados evanescentes en el gap de un ferroeléctrico, llamados estados de gap inducidos por el metal (MIGS, metal-induced gap states), que se forman en la unión metal/ferroeléctrico. Estos estados juegan un papel fundamental en los fenómenos de efecto túnel y en la formación de las barreras Schottky. En este capı́tulo discutimos hasta qué punto las caracterı́sticas de estos estados pueden predecirse a partir de las propiedades de volumen del ferroeléctrico, y cuáles están relacionadas con efectos intrı́nsecos de la interfase. En el capı́tulo 5 hablamos de la formación de dominios de polarización en condensadores ferroeléctricos. Hemos predicho por primera vez la formación de dominios de cierre en láminas delgadas ferroeléctricas a partir de primeros principios. A pesar de que su formación en láminas delgadas ferroeléctricas era considerada poco probable debido al gran acoplamiento entre la polarización y la deformación, esta estructura resulta ser increı́blemente general y proporciona un apantallado extremadamente eficiente. En el capı́tulo 6 se estudia el efecto de la deformación epitaxial sobre el acoplamiento entre la polarización y la rotación de los octaedros de oxı́geno en las superredes de PbTiO3 /SrTiO3 . El fuerte acoplamiento de estas dos inestabilidades en este sistema se explica en términos de un modelo covalente. En vista de los resultados del capı́tulo 5, también tenemos en cuenta la formación de dominios 191 de la polarización en las superredes. En estas superredes se han encontrado estructuras similares a las observadas en los condensadores ferroeléctricos, formandose vórtices de dipolos en las paredes de dominio. Por último, los resultados de este trabajo se resumen en las conclusiones. Appendix E Conclusiones Como se ha discutido ampliamente a lo largo de esta tesis, las láminas delgadas de perovskitas ofrecen una posibilidad fantástica para el diseño de sistemas multifuncionales. Un tema de gran importancia para el funcionamiento de dichos dispositivos son las condiciones de contorno electrostáticas, que pueden afectar de manera dramática a las propiedades estructurales y electrónicas de los materiales. El tema central de nuestro trabajo a lo largo de estos años ha sido precisamente el estudio desde primeros principios de las propiedades de apantallado de láminas delgadas de perovskitas. En esta memoria se ha señalado en varias ocasiones que el grado de desarrollo de las simulaciones desde primeros principios y de las técnicas experimentales en este campo han convergido de tal manera que, hoy en dı́a, tanto teóricos como experimentales podemos investigar en esencia el mismo tipo de sistemas. En este contexto, los cálculos desde primeros principios tienen dos papeles: constituyen una herramienta que nos permite explorar combinaciones de materiales y configuraciones, incluso antes de que éstas se sinteticen o detecten en el laboratorio, y sirven para complementan los resultados experimentales proporcionando interpretaciones fı́sicas que ayudan a optimizar las funcionalidades de los sistemas. Una fracción muy importante de nuestro trabajo en los últimos años se ha centrado en el estudio de los lı́mites de aplicabilidad de la DFT, que es método desde primeros principios más comúnmente empleado en el estudio de óxidos en láminas delgadas. Las aproximaciones LDA y GGA han proporcionado en los últimos años una información inestimable sobre las propiedades de estos materiales, pero tienen algunas limitaciones. Al aumentar la complejidad de los sistemas estudiados a partir de primeros principios han empezado a surgir problemas derivados del mal uso de estas aproximaciones. Hemos realizado un importante esfuerzo para proporcionar una guı́a completa y clara para aclarar las limitaciones de este método teórico. Hemos tratado de destacar las tı́picas huellas que permiten detectar resultados no fı́sicos consecuencia de esas limitaciones, centrándonos en un tipo de sistemas de especial relevancia: los condensadores ferroeléctricos. Estas limitaciones son especialmente importantes para el estudio de la estructura electrónica. Esto no quiere decir que afecten exclusivamente a la estructura electrónica, como hemos visto, la descripción patológica de las propiedades electrónicas tiene conse193 194 Resumen cuencias dramáticas sobre las propiedades estructurales del sistema, que es algo que ha sido sistemáticamente ignorado en el pasado. Algunas de las transferencias de carga patológicas que hemos atribuido a una deficiente descripción de la estructura electrónica debid a las aproximaciones LDA y GGA se han identificado en algunas ocasiones con estados de gap inducidos por el metal (MIGS: metal-induced gap states). En el capı́tulo 3 sugerimos algunas herramientas para distinguir claramente estas transferencias de carga, con significado fı́sico significativo y relevante, de las patológicas. El capı́tulo 4 está totamente dedicado a la caracterización de los estados evanescentes en condensadores ferroeléctricos. Aunque aún nos encontramos trabajando en este tema, hemos tratado de poner en contexto muchas propiedades que a menudo se discuten en la literatura y que a pesar de estar todas asociadas a los MIGS rara vez se relacionan con estos estado de forma explı́cita. Estos estados son estados de propagación en el lado metálico de una unión metal/aislante y sus energı́as se encuentran dentro del gap de este último. Cuando un electrón se encunetra con una barrera de potencial finita estos estados penetran en el aislante y decaen exponencialmente. Hemos visto que los reordenamientos de carga asociados a los MIGS juegan un papel importante en las propiedades de los condensadores y en particular en el alineamiento de la estructura de bandas. Las propiedades de estos estados están relacionadas con las caracterı́sticas de la estructura de banda compleja del aislante en volumen, aunque como se ha discutido en el capı́tulo 4, las propieddades intrı́nsecas de la interfase determinan en última instancia, sus distribuciones espacial y energética. Esto pone en relieve la importancia de un tratamiento explı́cito de la interfase teniendo en cuenta los detalles a nivel atómico, fundamentales en los dispositivos de láminas delgadas. A lo largo de los capı́tulos 3 y 4, que se dedican principalmente a las propiedades de los condensadores ferroeléctricos relacionadas con su estructura electrónica, se destaca la importancia de la mejora de los funcionales. Las aproximaciones LDA y GGA han demostrado ser válidas para describir las propiedades estructurales de las pelı́culas delgadas de óxidos, pero el descubrimiento de nuevas funcionalidades y acoplamientos entre las propiedades estructurales y electrónicas exige dar un paso más allá y empezar a trabajar con métodos más precisos. El método GW constituye una alternativa para la investigación de la estructura electrónica y tiene la ventaja de estar basado en la DFT. Si bien es cierto que estos métodos proporcionan una descripción muy precisa de la estructura electrónica de los materiales, siguen siendo demasiado costosos computacionalmente para ser aplicados a sistemas complejos reales, como los que se estudian en esta memoria. Por otro lado, los funcionales hı́bridos constituyen una opción prometedora para mejorar el actual conocimiento acerca de la fı́sica de láminas delgadas de óxidos. Los funcionales hı́bridos “tradicionales”, como el B3LYP o el B1, fueron desarrollados en el contexto de la quı́mica cuántica y han demostrado proporcionar una muy buena descripción de las energı́as de disociación, de las distancias de enlace y de las frecuencias de vibración, ası́ de los espectros de energı́a para la mayorı́a de las moléculas. Sin embargo, se ha encontrado que fallan al intentar reproducir las propiedades estructurales de algunos sólidos y de, en particular, de los ferroeléctricos. Afortunadamente ha habido importantes avances en esta dirección. En concreto, el desarrollo del funcional B1-WC (una 195 mezcla de intercambio exacto con el funcional GGA de Wu y Cohen, que proporciona una muy buena descripción de la estructura atómica de las perovskitas) abre la puerta al estudio de muchos fenómenos de sistemas complejos de óxidos que estaban fuera del alcance de la mayorı́a de las aproximaciones utilizadas en la actualidad. Aunque el uso de funcionales hı́bridos es mucho más exigente computacionalmente que el de LDA o GGA, dada la rápida evolución de la informática (tanto en el software como en el hardware) es de esperar que las diferencias se reduzcan en poco tiempo. Ya en la actualidad, dadas las limitaciones de los enfoques DFT más comunes, que han sido discutidos en esta memoria, una cuidada selección de los sistemas a simular puede proporcionar una enorme cantidad de información. También hemos investigado los dominios de polarización en láminas delgadas ferroeléctricas, tanto en condensadores como en superredes. En ambos tipos de sistemas, hemos observado la formación de de dominios de cierre, una estructura que se creı́a poco probable en los materiales ferroeléctricos debido a la energı́a elástica asociada. Tanto los cálculos desde primeros principios como las simulaciones de Hamiltoniano modelo han predicho la formación de los dominios de cierre en varios sistemas diferentes, desde condensadores de BaTiO3 /SrRuO3 (como se muestra en el capı́tulo 5 y la Ref. [55]) hasta láminas aisladas de PbTiO3 [184]. Estudios teóricos han encontrado que la estructura de paredes de dominio es sorprendentemente robusta independientemente material ferroeléctrico, el nivel de apantallado proporcionado por los electrodos (si existen), y el enfoque teórico utilizado para el estudio. El reciente desarrollo de la microscopı́a electrónica de transmisión con resolución subatómica ha permitido finalmente la observación experimental de tales estructuras [66], lo que confirma las predicciones teóricas propuestas pocos años antes. Se trata un buen ejemplo del nivel de predicción que han alcanzado las simulaciones desde primeros principios en los últimos tiempos. Ahora que los detalles acerca de la estructura de las paredes de dominio en estos sistemas está siendo caracterizada, es el momento de analizar otras propiedades asociadas. Por ejemplo, muy recientemente, se ha observado la conductividad de las paredes de dominio en láminas delgadas ferroeléctricas. Se observó por primera vez en láminas delgadas de BiFeO3 [10] y se atribuyó a una reducción del gap en las paredes de dominio, sin embargo, el cambio previsto en la estructura electrónica en las paredes estudiadas era demasiado pequeño para explicar la conductividad observada. También se sugirió que las paredes de dominio con polarizaciones enfrentadas y los campos eléctricos asociados podrı́an explicar la conductividad, pero recientemente se ha observado conductividad en PZT tetragonal donde la formación espontánea de las paredes de dominio polares es más improbable. En nuestra opinión, la explicación más razonable es la fijación de vacantes de oxı́geno en las paredes de dominio, algo que ya ha sido estudiado desde primeros principios en PbTiO3 en volumen [182]. La migración de las vacantes a las paredes de dominio y la fijación de estas últimas sugieren una concentración relativamente alta de defectos en estas zonas del material. Esta hipótesis se ve reforzada por los altos campos eléctricos que hemos encontrado las fronteras entre los dominios de cierre. Algunas de estas funcionalidades podrı́an optimizarse con un conocimiento detallado de las propiedades de la paredes de dominio más allá de su estructura, lo que podrı́a dar lugar al uso de las paredes 196 Resumen de dominio como elementos funcionales en los dispositivos de láminas ultra-delgadas. Naturalmente, la investigación desde primeros principios de tales propiedades, también saldrı́a beneficida de la utilización de un mejor funcional que proporcionase una mejor descripción de la estructura electrónica del sistema. El número de posibles funcionalidades que pueden inducirse en las superredes aumenta cada dı́a. Existe un gran número de materiales diferentes con una estructura similar, pero con propiedades completamente distintas, que pueden combinarse con un control atómico sobre la calidad de la interfase, dando lugar a propiedades absolutamente inimaginables. Hemos visto cómo surgen nuevos acoplamientos y fases como consecuencia de los efectos de las interfases en las superredes, propiedades que pueden ser explotadas para el diseño a medida de nuevos materiales artificiales. En este contexto, no sólo nuevas combinaciones de materiales deben ser exploradas, sino también nuevas geometrı́as que podrı́an reforzar una determinada propiedad en particular. Por ejemplo la estabilidad de los vórtices de polarización en nanoestructuras ferroeléctricas puede ser utilizada para diseñar nanopartı́culas con un momento toroidal o nanopilares quirales con actividad óptica sintonizable. La sı́ntesis de algunos de estos sistemas está todavı́a lejos de las posibilidades de las técnicas de experimentales actuales y algunos dispositivos experimentales siguen siendo demasiado complicados como para ser simulados por completo desde primeros principios. Por lo tanto, es fundamental la continua retroalimentación con las simulación con Hamiltonianos modelo, que conectan las dimensiones y las escalas de energı́a entre las simulaciones desde primeros principios y los experimentos. Afortunadamente, la colaboración entre los grupos teóricos y experimentales en este campo es muy estrecha, lo que proporciona un entorno de trabajo enormemente motivador. 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Lett., 88:232902, 2006. [205] X. Gonze and C. Lee. Dynamical matrices, born effective charges, dielectric permittivity tensors, and interatomic force constants from density-functional perturbation theory. Phys. Rev. B, 55:10355, 1997. Universidad de Cantabria Facultad de Ciencias Dpto. Ciencias de la Tierra y Física de la Materia Condensada Estudio desde primeros principios de mecanismos de apantallado del campo de depolarización en condensadores nanométricos. TESIS DOCTORAL Pablo Aguado Puente

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