Bonded tableau method for many-electron systems

The stmphctty of elementary transformattons on the system matrtx of a hnear system can be explmted for umfymg methods of finding canomcal forms, (A, B)mvartant subspaces, and system mverses Key Word Iodex~ontrol system synthesis, linear systems, polynomial equatmns, spectral factonzation, stochastic

The Feynman path integral method is applied to the many-electron problem of quantum chemistry. We begin with constructing new closure relations in terms of the linear combination of atomic orbital (LCAO) coefficients and investigate the transition amplitude and the partition function of the system i

A simple procedure is presented for obtaining the standard Young tableaux for the representation [( N/2) + S, (N/2) -S ] of the permutation group -U-., for an N-electron system in spin state S directly from the spin branching diagram. We redefine the coordinate axes of the branching diagram to obtai

A new approximation method based on the dominance of intra-pair correlations is proposed for calculating manyelectron valence bond wavefunctions. This "doubly-occupied orbital sea" valence bond method (DOS VB) gives accurate orbit& as well as energies. l3e computation time increases with the number

A method for rapidly computing electric dipolar susceptibilities of large systems such as semiconductor surfaces is given. Bond polarisabilities and bond-bond interactions are calculated by an ab initio technique. Bond interactions are also calculated by a point-dipole model where bond dipoles are a