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Transcript
Population Analysis Bader Charge & Bader volume Richard Bader from McMaster University, developed an intuitive way of dividing molecules into atoms called the Quantum Theory of Atoms in Molecules (QTAIM). His definition of an atom is based purely on the electronic charge density. Bader uses what are called zero flux surfaces to divide atoms. A zero flux surface is a 2-D surface on which the charge density is a minimum perpendicular to the surface. Typically in molecular systems, the charge density reaches a minimum between atoms and this is a natural place to separate atoms from each other. http://theory.cm.utexas.edu/henkelman/research/bader/ A partial charge is a charge with an absolute value of less than one elementary charge unit (that is, smaller than the charge of the electron). Partial charges are a property only of zones within the distribution, and not the assemblage as a whole The concept of a partial atomic charge is somewhat arbitrary, because it depends on the method used to delimit between one atom and the next (in reality, atoms have no clear boundaries). Partitioning the molecular wave function using some arbitrary, orbital based scheme. Mulliken population analysis Coulson's charges Natural charges CM1, CM2, CM3 charge models Partitioning of a physical observable derived from the wave function, such as electron density Bader charges Density fitted atomic charges Hirshfeld charges Maslen's corrected Bader charges Politzer's charges Density charges Mulliken population analysis For Simplicity Two atom each have one atomic orbital A B n m The molecular Orbital {j} j = Cn Yn+ CmYm Molecular Orbital is occupied by N (2) electrons, suppose this population may be Considered as divided into three sub-populations. In space the detail distribution is Nj2 = NCn 2Yn2+ 2N CnCm Smn (YnYm /Smn) + NCm2 Ym2 The three wavefunction are normalized So, N = NCn 2+ 2N CnCm Smn + NCm2 A B Overlap term Discussion In Previous slide we assume there is only two atom with single atomic orbital each (example- D2), but for more then single orbital and more then two atom, we have to generalized this. General Approach If the coefficients of the basis functions in the molecular orbital are Cμi for the μ'th basis function in the i'th molecular orbital, the density matrix terms are: m,n atomic orbital of atoms Population Matrix Overlap Matrix of the basis function Gross Orbital Product for Orbital n = ∑ Gross atom population = ∑ m m = ∑∑ n m N/2 Total Charge at atom A =2 ∑ ∑∑ n m i N/2 = 2 ∑ ∑ ∑ CniCmi Smn i n m Total Charge gain/loss by atom A Atomic number Bader charges The chemical bonding of a system based on the topology of the quantum charge density. In addition to bonding, atoms in molecules (AIM) allows the calculation of certain physical properties on a per-atom basis, by dividing space up into atomic volumes containing exactly one nucleus. In quantum theory of atoms in molecules (QTAIM) an atom is defined as a proper open system, i.e. a system that can share energy and electron density, which is localized in the 3D space. Each atom acts as a local attractor of the electron density, and therefore it can be defined in terms of the local curvatures of the electron density. In computation Gaussian Mullikan r = Total r { F atom r + Phenalene r } Bader VASP Charge of F = r dV r 2 CASTEP Hirshfeld Mullikan Population analysis in CASTEP is performed using a projection of the PW states onto a localized basis using a technique described by Sanchez-Portal et al. (1995). Population analysis of the resulting projected states is then performed using the Mulliken formalism (Mulliken, 1955). This technique is widely used in the analysis of electronic structure calculations performed with LCAO basis sets Thank You