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Hartree-Fock approximation equation

To properly describe electronic rearrangement and its dependence on both nuclear positions and velocities, it is necessary to develop a time-dependent theory of the electronic dynamics in molecular systems. A very useful approximation in this regard is the time-dependent Hartree-Fock approximation (34). Its combination with the eikonal treatment has been called the Eik/TDHF approximation, and has been implemented for ion-atom collisions.(21, 35-37) Approximations can be systematically developed from time-dependent variational principles.(38-41) These can be stated for wavefunctions and lead to differential equations for time-dependent parameters present in trial wavefunctions. [Pg.319]

The only term for which no explicit form can be given, i. e the big unknown, is of course Exc- Similarly to what we have done within the Hartree-Fock approximation, we now apply the variational principle and ask what condition must the orbitals cp fulfill in order to minimize this energy expression under the usual constraint of ((p I (pj) = ,j The resulting equations are (for a detailed derivation see Parr and Yang, 1989) ... [Pg.62]

We applied the Liouville-von Neumann (LvN) method, a canonical method, to nonequilibrium quantum phase transitions. The essential idea of the LvN method is first to solve the LvN equation and then to find exact wave functionals of time-dependent quantum systems. The LvN method has several advantages that it can easily incorporate thermal theory in terms of density operators and that it can also be extended to thermofield dynamics (TFD) by using the time-dependent creation and annihilation operators, invariant operators. Combined with the oscillator representation, the LvN method provides the Fock space of a Hartree-Fock type quadratic part of the Hamiltonian, and further allows to improve wave functionals systematically either by the Green function or perturbation technique. In this sense the LvN method goes beyond the Hartree-Fock approximation. [Pg.289]

The Hartree-Fock approximation leads to a set of coupled differential equations (the Hartree-Fock equations), each involving the coordinates of a single electron. While they may be solved numerically, it is advantageous to introduce an additional approximation in order to transform the Hartree-Fock equations into a set of algebraic equations. [Pg.25]

Hartree-Fock Equations. The set of differential equations resulting from application of the Born-Oppenheimer and Hartree-Fock Approximations to the many-electron Schrodinger Equation. [Pg.760]

Spin Orbital. The form of Wavefunction resulting from application of the Hartree-Fock Approximation to the Electronic Schrodinger Equation. Comprises a space part (Molecular Orbital) and one of... [Pg.769]

Although in principle an exact solution to the Schrodinger equation can be expressed in the form of equation (A.13), the wave functions and coefficients da cannot to determined for an infinitely large set. In the Hartree-Fock approximation, it is assumed that the summation in equation (A.13) may be approximated by a single term, that is, that the correct wave function may be approximated by a single determinantal wave function , the first term of equation (A.13). The method of variations is used to determine the... [Pg.222]

Our approximations so far (the orbital approximation, LCAO MO approximation, 77-electron approximation) have led us to a tt-electronic wavefunction composed of LCAO MOs which, in turn, are composed of 77-electron atomic orbitals. We still, however, have to solve the Hartree-Fock-Roothaan equations in order to find the orbital energies and coefficients in the MOs and this requires the calculation of integrals like (cf. eqns (10-3.3)) ... [Pg.205]

To find the true Hartree-Fock orbitals, one must use a complete set in (1.295), which means using an infinite number of gk s. As a practical matter, one must use a finite number of basis functions, so that one gets approximations to the Hartree-Fock orbitals. However, with a well-chosen basis set, one can approach the true Hartree-Fock orbitals and energy quite closely with a not unreasonably large number of basis functions. Any MOs (or AOs) found by iterative solution of the Hartree-Fock-Roothaan equations are called self-consistent-field (SCF) orbitals, whether or not the basis set is large enough to give near-Hartree-Fock accuracy. [Pg.287]

Expressions (29.8) and (29.9) are the Hartree-Fock equations in a multi-configurational approximation [222], or the Hartree-Fock-Jucys equations. They must be solved together with the equations... [Pg.349]

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See also in sourсe #XX -- [ Pg.46 ]



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