Fock operator expectation value

The density amplitudes can usually be calculated more efficiently than the density operator because they depend on only one set of variables in a given representation although there are cases, such as shown below for the time-dependent Hartree-Fock density operator, where the advantages disappear and it is convenient to calculate the density operator. Expectation values of operators A t) follow from the trace over the density operator, as... 

The occupation number vectors are basis vectors in an abstract linear vector space and specify thus only the occupation of the spin orbitals. The occupation number vectors contain no reference to the basis set. The reference to the basis set is built into the operators in the second quantization formalism. Observables are described by expectation values of operators and must be independent of the representation given to the operators and states. The matrix elements of a first quantization operator between two Slater determinants must therefore equal its counterpart of the second quantization formulation. For a given basis set the operators in the Fock space can thus be determined by requiring that the matrix elements between two occupation number vectors of the second quantization operator, must equal the matrix elements between the corresponding two Slater determinants of the corresponding first quantization operators. Operators that are considered in first quantization like the kinetic energy and the coulomb repulsion conserve the number of electrons. In the Fock space these operators must be represented as linear combinations of multipla of the ajaj... 

Fock spaces) and corresponding quantum mechanical operators. The connection between different formulations must be that they give the same expectation values of operators. 

Boys and Cook refer to these properties as primary properties because their electronic contributions can be obtained directly from the electronic wavefunction As a matter of interest, they also classified the electronic energy as a primary property. It can t be calculated as the expectation value of a sum of true one-electron operators, but the Hartree-Fock operator is sometimes written as a sum of pseudo one-electron operators, which include the average effects of the other electrons. 

The Lagrange multipliers can be interpreted as MO energies, i.e. they expectation value of the Fock operator in the MO basis (multiply eq. (3.41) by the left and integrate). 

In his pioneering work Baetzold used the Hartree-Fock (HF) method for quantum mechanical calculations for the cluster structure (the details are summarized in Reference 33). The value of the HF procedure is that it yields the best possible single-determinant wave function, which in turn should give correct values for expectation values of single-particle operators such as electric moments and... 

As a simple model, we confine our attention just to a single mode Ha(t) of the Hamiltonian (23). Note that neither any instantaneous eigenstate of Ha(t) is an exact quantum state nor e-/3ii W is a density operator. To calculate the thermal expectation value of an operator A, one needs either the Heisenberg operator Ah or the density operator pa(t) = UapaUa Now we use the time-dependent creation and annihilation operators (24), invariant operators, to construct the Fock space. 

The structure of the parametric UA for the 4-RDM satisfies the fourth-order fermion relation (the expectation value of the commutator of four annihilator and four creator operators [26]) for any value of the parameter which is a basic and necessary A-representability condition. Also, the 4-RDM constructed in this way is symmetric for any value of On the other hand, the other A-representability conditions will be affected by this value. Hence it seems reasonable to optimize this parameter in such a way that at least one of these conditions is satisfied. Alcoba s working hypothesis [48] was the determination of the parameter value by imposing the trace condition to the 4-RDM. In order to test this working hypothesis, he constructed the 4-RDM for two states of the BeHa molecule in its linear form Dqo/,. The calculations were carried out with a minimal basis set formed by 14 Hartree-Fock spin orbitals belonging to three different symmetries. Thus orbitals 1, 2, and 3 are cr orbitals 4 and 5 are cr and orbitals 6 and 7 are degenerate % orbitals. The two states considered are the ground state, where... 

The energy (to be evaluated from Eq. (51)) appears as a constant term, consistent with the fact that the expectation values of the last two terms with respect to fk automatically vanish. The fP are the matrix elements of the generalized Fock operator, Eq. (52). 

Hartree-Fock theory makes the fundamental approximation that each electron moves in the static electric field created by all of die other electrons, and then proceeds to optimize orbitals for all of the electrons in a self-consistent fashion subject to a variational constraint. The resulting wave function, when operated upon by the Hamiltonian, delivers as its expectation value the lowest possible energy for a single-detenninantal wave function formed from the chosen basis set. 

The correlation energy, Econ, is defined as the difference between If exact, the experimentally determined ground state energy of a system, and Ess, the expectation value of the Hartree-Fock operator. 

Since the EP is the expectation value of a one-electron operator r-1, its calculation is correct to one order higher than the wavefunction used [5]. This means that the quality of the Hartree-Fock (HF) SCF wavefunction is generally appropriate for calculating EP when the molecule is in ground electronic state. For excited molecules correlated wavefunction is necessary for EP calculations [6]. 

Blume and Watson,97- 98 using spherical tensor methods, were able to reduce the second part of this expression to a form suitable for calculation. They derived expectation values of this operator from non-relativistic atomic Hartree-Fock wavefunctions and hence the spin-orbit coupling constant, , for many atoms and ions. Consistent results for atoms were also obtained by Hinkley" using wavefunctions both from exponential basis sets100 and from gaussian basis sets.101 Agreement with experiment is good. 

It appears, therefore, that it is possible to obtain accurate expectation values of the spin-orbit operators for diatomic molecules. Matcha et a/.112-115 have provided general expressions for the integrals involved and from their work Hall, Walker, and Richards116 derived the diagonal one-centre matrix elements of the spin-other-orbit operator for linear molecules. Provided good Hartree-Fock wavefunctions are available, these should be sufficient for most calculations involving diatomic molecules. 

Let us briefly discuss the relationship between approaches which use basis sets and thus have a discrete single-particle spectrum and those which employ the Hartree-Fock hamiltonian, which has a continuous spectrum, directly. Consider an atom enclosed in a box of radius R, much greater than the atomic dimension. This replaces the continuous spectrum by a set of closely spaced discrete levels. The relationship between the matrix Hartree-Fock problem, which arises when basis sets of discrete functions are utilized, and the Hartree-Fock problem can be seen by letting the dimensions of the box increase to infinity. Calculations which use discrete basis sets are thus capable, in principle, of yielding exact expectation values of the hamiltonian and other operators. In using a discrete basis set, we replace integrals over the continuum which arise in the evaluation of expectation values by summations. The use of a discrete basis set may thus be regarded as a quadrature scheme. 

As it is the case for complicated problems where expansions into known functions are required, the final computational expressions are cast in matrix form. By forming the expectation value of the monoelectronic Hartree-Fock operator and by applying the variational procedure for the LCAO coefficients, C (k), the following system of equations, of size is obtained ... 

The ADMA and SADMA methods generate ab initio quality density matrices P for large molecules M, while avoiding the computation of macromolecular wave functions. At the Hartree-Fock level, the first-order density matrix P fully determines all higher-order density matrices. Within the Hartree-Fock framework, expectation values for one-electron and two-electron operators can be computed using the first-order and second-order density matrices. Consequently, the ADMA and SADMA methods provide new possibilities for adapting quantum-chemical techniques for macromolecules. 

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