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Tutorial lecture 1 in Kazan Federal University The Problems of Electric Polarization Dielectrics in Static Field Yuri Feldman 1 Ancient times 1745 first condenser constructed by Cunaeus and Musschenbroek And is known under name of Leyden jar 1837 Faraday studied the insulation material,which he called the dielectric Middle of 1860s Maxwell’s unified theory of electromagnetic phenomena 1847 Ottaviano-Fabrizio Mossotti = n2 1879 Clausius 2 1887 Hertz 1897 Drude Lorenz 1912 Debye Internal field Dipole moment Robert Cole 3 Dielectric response on mesoscale Dielectric spectroscopy is sensitive to relaxation processes in an extremely wide range of characteristic times ( 10 5 - 10 -12 s) Broadband Dielectric Spectroscopy Time Domain Dielectric Spectroscopy; Time Domain Reflectometry 10-6 10-4 10-2 102 0 104 106 108 1010 1012 f (Hz) Porous materials and colloids Macromolecules Glass forming liquids Clusters Single droplets and pores Water ice 4 Dielectric response in biological systems Dielectric spectroscopy is sensitive to relaxation processes in an extremely wide range of characteristic times ( 10 5 - 10 -11 s) Broadband Dielectric Spectroscopy Time Domain Dielectric Spectroscopy 10-1 0 101 102 103 104 105 106 107 108 ice Cells Proteins 109 1010 H H3N+ — C — COO R Amino acidsAsn Ala Asp Arg Cys Glu Gln His Ile Leu Lys Met Phe Ser Thr Trp Tyr Val 1011 1012 f (Hz) Water DNA, RNA Lipids Tissues P N+ -Dispersion - Dispersion - Head group region - Dispersion - Dispersion 5 Electric dipole - definition The electric moment of a point charge relative to a fixed point is defined as er, where r is the radius vector from the fixed point to e. Consequently, the total dipole moment of a whole system of charges ei relative to a fixed origin is defined as: m ei ri i A dielectric substance can be considered as consisting of elementary charges ei , and ei eri 0 i i if it contains no net charge. If the net charge of the system is zero, the electric moment is independent of the choice of the origin: when the origin is displaced over a distance ro, the change in m is given by: 6 6 m ei ro ro ei i i Thus m equals zero when the net charge is zero. Then m is independent of the choice of the origin. In this case equation (1.1) can be written in another way by the introduction of the electric centers of gravity of the positive and the negative charges. These centers are defined by the equations: er r e r Q and i i positive p i positive e r r e i i negative n i negative p rn Q in which the radius vectors from the origin to the centers are represented by rp and rn respectively and the total positive charge is called Q. m (rp rn )Q 7 The difference rp-rn is equal to the vector distance between the centers of gravity, represented by a vector a, pointing from the negative to the positive center ( Fig.1). +Q a rp - Q rn Thus we have: m aQ Therefore the electric moment of a system of charges with zero net charge is generally called the electric dipole moment of the system. A simple case is a system consisting of only two point charges + e and - e at a distance a. Such a system is called a (physical) electric dipole, its moment is equal to ea, the vector a pointing from the negative to the positive charge. Under the influence of the external electrical field, the positive and negative charges in the particle are moved apart: the particle is polarized. In general, these induced dipoles can be treated as ideal; permanent dipoles, however, may generally not be treated as ideal 8 when the field at molecular distances is to be calculated. The values of molecular dipole moments are usually expressed in Debye units. The Debye unit, abbreviated as D, equals 10-18 electrostatic units (e.s.u.). The permanent dipole moments of non-symmetrical molecules generally lie between 0.5 and 5D. It is come from the value of the elementary charge eo that is 4.410-10 e.s.u. and the distance s of the charge centers in the molecules amount to about 10-9-10-8 cm. In the case of polymers and biopolymers one can meet much higher values of dipole moments ~ hundreds or even thousands of Debye units. To transfer these units to SI system one have to take into account that 1D=3.310-30 coulombsm. 9 Types of polarization Deformation polarization a. Electron polarization - the displacement of nuclear and electrons in the atom under the influence of external electric field. As electrons are very light they have a rapid response to the field changes; they may even follow the field at optical frequencies. - + + + Electric Field b. Atomic polarization - the displacement of atoms or atom groups in the molecule under the influence of external electric field. 10 Orientation polarization: The electric field tends to direct the permanent dipoles. Electric field +e -e 11 Ionic Polarization In an ionic lattice, the positive ions are displaced in the direction of the applied electric field whilst the negative ions are displaced in the opposite direction, giving a resultant dipole moment to the whole body. + - + + - - - - + + + -+ - + -- + + - + + - +- + - + - + + + -++ - + - ++ + Electric field 12 The vector fields E and D. For measurement inside matter, the definition of E in vacuum, cannot be used. There are two different approaches to the solution of the problem how to measure E inside matter. They are: 1. The matter can be considered as a continuum in which, by a sort of thought experiment, virtual cavities were made. (Kelvin, Maxwell). Inside these cavities the vacuum definition of E can be used. 2. The molecular structure of matter considered as a collection of point charges in vacuum forming clusters of various types. The application here of the vacuum definition of E leads to a so-called microscopic field (Lorentz, Rosenfeld, Mazur, de Groot). If this microscopic field is averaged, one obtains the macroscopic or Maxwell field E . 13 For the solution of this problem of how to determine the electric field The main problem of physics of dielectrics is inside matter, it is also possible first to introduce a new vector field D in passing from a phenomenological macroscopic such a way that for this field the source equation will be valid. linear dielectric response to the microscopic divDof electrons, 4 structure in terms nuclei, atoms, molecules and ions. Inisgeneral case the problem According to Maxwell, matter regarded as a continuum. To use theis still unresolved definition of the field completely. vector E, a cavity has to be made around the point where the field is to be determined. However, the force acting upon a test point charge in this cavity will generally depend on the shape of the cavity, since this force is at least partly determined by effects due to the walls of the cavity. This is the reason that two vector fields defined in physics of dielectrics: The electric field strength E satisfying curlE=0, and the dielectric displacement D, satisfying div D=4. 14 The Maxwell continuum can be treated as a dipole density of matter. Difference between the values of the field vectors arises from differences in their sources. Both the external charges and the dipole density of the piece of matter act as sources of these vectors. The external charges contribute to D and to E in the same manner. Because of the different cavities in which the field vectors are measured, the contribution of dipole density to D and E are not the same. It can be shown that D E 4P where P called the POLARIZATION. Generally, the polarization P depends on the electric strength E. The electric field polarizes the dielectric. The dependence of P on E can take several forms: P E 15 The polarization proportional to the field strength. The proportional factor is called the dielectric susceptibility. D E 4 P ( 1 4 )E E in which is called the dielectric permittivity. It is also called the dielectric constant, because it is independent of the field strength. It is, however, dependent on the frequency of applied field, the temperature, the density (or the pressure) and the chemical composition of the system. E D Dielectric sample D E 16 Polar and Non-polar Dielectrics To investigate the dependence of the polarization on molecular composition, it is convenient to assume the total polarization P to be divided into two parts: the induced polarization P caused by the translation effects, and the dipole polarization P caused by the orientation of the permanent dipoles. 1 E P P 4 A non-polar dielectric is one whose molecules possess no permanent dipole moment. A polar dielectric is one in which the individual molecules possess a dipole moment even in the absence of any applied field (i.e. the center of positive charge is displaced from the center of negative charge). 17 Induced and orientation polarizations Induced polarization Orientation polarization PP N kN k (Eμi )k α k k k k Nk is the number of particles per volume unit; 1 3 a is the scalar polarizability of a particle ; 2 Ei is the Internal Field, the average field strength acting upon that It isvalue definedofasthe thepermanent total electric field at the position is the dipole vector μk particle. of the particle minusover the field due to the particle itself. averaged all orientations. k is the index referred to the k-th kind of particle. 18 Orientation polarization, Average dipole moment The energy of the random oriented permanent dipole in the electric field dependent on the part of the electric field tending to direct the permanent dipoles. This part of the field is called the directing field Ed. Wk - μk Ed Ed cos k Averaging W Ed cos E The relative probabilities of the various orientations of dipole depend on this energy according to Boltzmann’s distribution law: Ed cos 1 p d ~ exp sin d kT 2 19 cos cos e 0 e Ed cos kT Ed cos 1 sin d 2 1 sin d 2 kT 0 a 1 a x e xdx a a x e dx a 1 [ xex e x ]aa e a e a 1 1 cot anh ( a ) L( a ), x a a a a [ e ] a e e a a E cos where d kT x L(a) is called Langeven function E d a kT and In Fig. the Langeven function y L(a) is plotted against a. L(a) has a limiting value 1, which was to be expected since this is the maximum y=1/3 a 1.0 y=1 of cos. For small values of a, <cos> is linear in Ed: 0.8 y=L( a ) 0.6 0.4 0.2 0.0 0 1 2 3 4 5 6 7 8 E 1 cos a d 3kT 3 if 0 a 1 a 20 The approximation of cos may be used as long as E 0.1kT a d 0.1 or E . kT d At room temperature (T=300o K) this gives for a dipole of 4D: E d 0.1kT = 3 105 v/cm For a value of smaller than the large value of 4D, the value calculated for Ed is even larger. In usual dielectric measurements, Ed is much smaller than 105 v/cm and the use of cos is allowed. From the linear response approximation it follows that: 2 μ cos Ed 3kT Substituting this into the main relationship for the orientation polarization, we get: 2 P N k ( Ed ) k k 21 Fundamental equation 1 E = P P 4 k2 1 E = N k k ( Ei ) k ( Ed ) k 4 3kT k This is the fundamental equation is the starting point for expressing Ei and Ed as functions of the Maxwell field E and the dielectric constant . 22 Dipole moments and electrostatic problems Eo Z 1 a 2 Let us put a dielectric sphere of radius a and dielectric constant 2, in a dielectric extending to infinity (continuum), with dielectric constant 1, to which an external electric field is applied. Outside the sphere the potential satisfies Laplace's equation =0, since no charges are present except the charges at a great distance required to maintain the external field. On the surface of the sphere Laplace's equation is not valid, since there is an apparent surface charge. Inside the sphere, however, Laplace's equation can be used again. Therefore, for the description of , we use two different functions, 1 and 2, outside and inside the sphere, respectively. 23 Let us consider the center of the sphere as the origin of the coordinate system, we choose z-axis in the direction of the uniform field. Following relation in the terms of Legendre polynomial represents the general solution of Laplace’s equation: B 1 An r n nn1 Pn (cos ) r n 0 D 2 Cn r n nn1 Pn (cos ) r n 0 Eo Z 1 a 2 The boundary conditions are: 1. 2. 3. 4. 1 r E0 z E0r cos 1 r a 2 r a Since is continuous across a boundary d1 d2 1 2 dr r a dr r a since the normal component of D must be continuous at the surface of the sphere At the center of the sphere (r=0) 2 must not have a singularity. 24 The total field E2 inside the sphere is accordingly is given by: E2 3 1 E0 2 1 2 A spherical cavity in dielectric In the special case of a spherical cavity in dielectric (1=; 2=1), equation is reduced to: 3 EC E0 2 1 2=1 1 = This field is called the "cavity field". The lines of dielectric displacement given by Dc=3Do/(2+1) are more dens in the surrounding dielectric, since D is larger in the dielectric than in the cavity 25 A dielectric sphere in vacuum For a dielectric sphere in a vacuum (1=1; 2=), the equation is reduced to: 3 E E0 2 1 where E is the field inside the sphere. The density of the lines of dielectric displacement Ds is higher in the sphere than in the surrounding vacuum, since inside the sphere Ds=3Eo/(+2). Consequently, it is larger than Eo. 2 = 1=1 The field outside the sphere due to the apparent surface charges is the same as the field that would be caused by a dipole m at the center of the sphere, surrounded by a vacuum, and given by: 1 3 m a E0 2 26 Type of interactions Two types of interaction forces: -Short range forces- interaction between nearest neighbors: • Chemical bonds, • Van der Waals attraction, • Repulsion forces, etc. Long rang dipolar interaction forces Dipole-dipole interaction Dipole -charge interaction Due to the long range of the dipolar forces an accurate calculation of the interaction of a particular dipole with all other dipoles of a specimen would be very complicated. The different approaches where developed for solving this problem. 27 Lorentz’s method 28 Non-polar dielectrics. Lorentz's field. Clausius-Massotti formula. The apparent surface For a non-polar system the fundamental equation for the dielectric permittivity charges 1 (2.49) is simplified to: E = N (E ) 4 k k i k E k _ _ __ E In this case, only the relation between the internal field and the Maxwell field has to _ be determined. Let us use the Lorentz approach in this case. _ He calculated _the internal field in homogeneously polarized matter as the field in a virtual spherical cavity. EC 3 E 2 1 + Lorentz’s field 2 Real cavity EL 3 E Lines of dielectric displacement + + + ++ Virtual cavity 29 1 E = N k k ( Ei ) k k 4 For a pure compound (k=1) 2 Ei E L E 3 Clausius-Massotti formula 1 4 N 2 3 30 Debye theory; Gases and polar molecules in non-polar solvent k2 1 E = N k k (Ei ) k (E d ) k 4 3kT k k 1; Ed E i E L 2 3 E 1 4 2 N 2 3 3kT This is generally called thethe Debye equation. It is was the first relationship that But in many cases, however, Debye equation in considerable made the connection between the molecular parameter substance disagreement with the experiment. It works very nice for gasesofatthe normal being tested and theone phenomenological (macroscopic) pressures. In this case has -1<<1 and equation can beparameter written as:that can be experimentally measured. 2 1 = 4N 3 kT 31 The reaction field and Onsager’s approach When a molecule with permanent dipole strength is surrounded by other particles, the inhomogeneous field of the permanent dipole polarizes its environment. In the surrounding particles moments proportional to the polarizability are induced, and if these particles have a permanent dipole moment their orientation is influenced. To calculate this effect one can use a simple model: an ideal dipole in a center of a spherical cavity. The inhomogeneous field of the permanent dipole Electric dipole field lines Line of force in the dipole field 32 The reaction field of a non-polarizable point dipole Let us assume that only one kind of molecule is presented and a is value approximately equal to what is generally considered to be the “molecular radius” Solving the Laplace equation with slightly different boundary conditions : z a 1 r 0 1 r a 2 r a 1. 2. d d 1 2 dr r a dr r a 3. We can calculate: The field in the cavity is a superposition of the dipole field in vacuum and a uniform field R, given by: 1 2( 1) R 2 1 1 2( 1) and the factor of the reaction field is equal to f a 3 2 1 a 3 33 33 Formally, the field of dielectric can be described as the field of a virtual dipole c at the center of the cavity, given by: 3 c 2 1 The presented model involves a number of simplifications, since the dipole is assumed to be ideal and located at the center of the molecule, which is supposed to be spherical and surrounded by a continuous dielectric. The reaction field of a polarized point dipole In this case the permanent dipole has an average polarizability , and therefore the reaction field R induces a dipole R and satisfies the equation: R f( μ R ) Under the influence of the reaction field the dipole moment is increased considerably, the increased moment is: μ μ R * n2 1 3 2 a n 2 Considering We can obtain that n2 2 1 n 2 2 2 n 2 3 In the case of polar dielectrics, the molecules have a permanent dipole moment , and both parts of the fundamental must be taken into account. k2 1 E = N k k ( Ei ) k ( Ed ) k 4 3kT k In the case of non-polar liquids the internal field can be considered as the sum of two parts; one being the cavity field and another the reaction field of the dipole induced in the molecule Ei=Ec+R. 35 For polar molecules the internal field can also built up from the cavity field and the reaction field, taking into account now the reaction field of the total dipole moment of the molecule. z a The angle between the reaction field of the permanent part of the dipole moment and the permanent dipole moment itself will be constant during the movements of the molecule. It means that in a spherical cavity the permanent dipole moment and the reaction field caused by it will have the same direction. Therefore, this reaction field R does not influence the direction of the dipole moment of the molecule under consideration, and does not contribute to the directing field Ed. On the other hand, the reaction field does contribute to the internal field Ei, because it polarizes the molecule. As a result, we find a difference between the internal field Ei and the directing field Ed. 36 Since the reaction field R belongs to one particular orientation of the dipole moment, the difference between Ei and Ed will give by the value of the reaction field averaged over all orientations of the polar molecule: Ei - Ed R z a The direction field Ed can be obtained by the following procedure: ) remove the permanent dipole of a molecule without changing its polarizability; ) let the surrounding dielectric adapt itself to the new situation; ) then fix the charge distribution of the surroundings and remove the central molecule. The average field in the cavity so obtained is equal to the value of Ed that is to be calculated, since we have eliminated the contribution of R to Ei by removing the permanent dipole of the molecule. 37 9kT ( )(2 ) 2 4N ( 2) 2 This equation is generally called the Onsager equation. It makes possible the computation of the permanent dipole moment of a molecule from the dielectric constant of the pure dipole liquid if the density and are known. 38 Relationships between the different kinds of electric fields In this case of the internal field can be considered In order to describe of matter the different kinds of The non-polar liquidspolarization as the sum of two parts; one being the cavity field electric fields where introduced : Maxwell’s field Efield field ; internal and another that is the reaction of the dipole Ei ; Lorentz field EL ; direction field Ed reaction field R and induced in the molecule: Polar molecules 2 the cavity field EC E E E R For polar molecules the internal field can also built up from the cavity field and the reaction field, Itaking into L accountCnow the reaction field of the total dipole Let usof the consider moment molecule. the relationships between these 3 E fields in thefield different systems. Since the reaction R belongs to one particular orientation of the dipole moment, the difference between Ei and Ed will give by the value of the reaction Gases and polar molecules in non-polar solvent field averaged over all orientations of the polar molecule: Ed E I Ei E - LEd EC RR 2 3 E The Kirkwood –Froehlich approach In the above approximations we considered nonpolar systems, polar dilute systems and polar systems without short range interactions. In all these cases the dipole-dipole interactions between molecules where not taking into account. A more general theory was developed by Kirkwood and subsequently refined by Froehlich. This approach takes into account the dipole-dipole interactions, which appears in a more dense state under the influence of the short range interactions 40 In this case the external field working in the sphere is the cavity field 3 E0 = EC E 2 1 N dipoles i E is the Maxwell field in the material outside the sphere 1 = 4n E0 1 1 2 e A e M 0 0 3kTn E E 0 n Here n=N /V is the number density, and the tensor A plays the role of a polarizability; N-N molecules are considered to form a continuum N N N M 0 i j 2 i 1 j 1 0 M = i For non polarizable molecules i =1 e A e 0 0 4 3 M 2 0 1 = V 2 1 3kT M2 N 0 i 1 N dX i M exp( U / kT ) N dX exp( U / kT ) 41 In this equation the superscript N to dX to emphasize that the integration is performed over the positions and orientations of N molecules (here dX=r2sindrdd, is the expression for a volume element in spherical coordinates). Since i is a function of the orientation of the i-th molecule only, the integration over the positions and orientations of all other molecules, denoted as N -i, can be carried out first. In this way we obtain (apart from a normalizing factor) the average moment of the sphere in the field of the i-th dipole with fixed orientation. The averaged moment, denoted by Mi*, can be written as: N dipoles i M i* N i dX M exp( U / kT ) N i dX exp( U / kT ) The average moment Mi* is a function of the position and orientation of the i-th molecule only. Denoting the positionM andi* orientation coordinates of the i-th molecule by Xi and using a weight factor p(Xi) p(X i ) N 1 dX exp( U / kT ) N dX exp( U / kT ) 42 M N 2 0 p( X i i M i* dX i N p( X i i M i* dX i i 1 N i M i* N i dX cosij exp( U / kT ) N i dX exp( U / kT ) j=1 M2 N 0 N 2 p( X i ) N -i dX cos ij exp( U / kT ) N -i dX exp( U / kT ) j 1 cos ij p( X i ) N -i dX cos ij exp( U / kT ) M 0 N 2 N -i dX exp( U / kT ) 2 N cos j 1 ij dX i dX i 43 ( - 1)(2 + 1) N N 2N i * i p( X i M i dX cos ij 12 3kT 3kT j 1 The left part of the Onsager equation for the non polarized molecules The deviations of Mi* from the value i are the result of molecular interactions between the i-th molecule and its neighbors. It is well known that liquids are characterized by short-range order and longrange disorder. The correlations between the orientations (and also between positions) due to the short-range ordering will lead to values of Mi* differing from i. This is the reason that Kirkwood introduced a correlation factor g which accounted for the deviations of N i * i 2 p ( X M dX cosij i i j 1 g 1 2 p( X from the value 2: N i i M dX cosij * i i j 1 44 ( - 1)(2 + 1) N g 2 12 3kT When there is no more correlation between the molecular orientations than can be accounted for with the help of the continuum method, one has g=1 we are going to Onsager relation for the non-polarizable case, for rigid dipoles with =1. An approximate expression for the Kirkwood correlation factor can be derived by taking only nearest-neighbors interactions into account. In that case the sphere is shrunk to contain only the i-th molecule and its z nearest neighbors. We then have: result of the integration will be not depend on N 1 Since after averaging the dX i j exp( U / kT ) j=1 all terms the summation * with =z+1.and we may write: theMvalue of j , in areN equal i z dX z N 1 exp( U / kT ) gi dX 1 Nz- icos cos ij exp( ij U / kT ) g 1 + p( X i )dX j 1 N -i dX exp( U / kT ) 45 g will be different from 1 when <cosij>0, i.e. when there is correlation between the orientations of neighboring molecules. When the molecules tend to direct themselves with parallel dipole moments, <cosij> will be positive and g>1. When the molecules prefer an ordering with anti-parallel dipoles, g <1. Approximation of Fröhlich 9 kT 2 g 2 4 2 2 46 Main relationships in static dielectric theory Non-polar systems 1 4 N 2 3 Polar diluted systems 2 1 = 4N Debye equation 3 kT Polar systems z 9kT ( )(2 ) 4N ( 2) 2 2 Clausius-Mossotti equation a Onsager Equation Polar systems, short range interactions 9 kT 2 g 2 4 2 2 Kirkwood-Fröhlich equation 47