General factorization relations and consistency conditions in the sudden approximation via infinite matrix inversion

C. K. Chan, D. K. Hoffman, J. W. Evans
1985 Journal of Chemical Physics  
Local, i.e., multiplicative, operators satisfy well-known linear factorization relations wherein matrix elements (between states associated with a complete set of wave functions) can be obtained as a linear combination of those out of the ground state (the input data). Analytic derivation of factorization relations for general state input data results in singular integral expressions for the coefficients, which can, however, be regularized using consistency conditions between matrix elements
more » ... matrix elements out of a single (nonground) state. Similar results hold for suitable "symmetry class" averaged matrix elements where the symmetry class projection operators are "complete. " In several cases where the wave functions or projection operators incorporate orthogonal polynomial dependence, we show that the ground state factorization relations have a simplified structure allowing an alternative derivation of the general factorization relations via an infinite matrix inversion procedure. This form is shown to have some advantages over previous versions. In addition, this matrix inversion procedure obtains all consistency conditions (which is not always the case from regularization of singular integrals). Disciplines Biological and Chemical Physics | Physics Comments . "General factorization relations and consistency conditions in the sudden approximation via infinite matrix inversion. Local, i.e., multiplicative, operators satisfy well-known linear factorization relations wherein matrix elements (between states associated with a complete set of wave functions) can be obtained as a linear combination ofthose out of the ground state (the input data). Analytic derivation of factorization relations for general state input data results in singular integral expressions for the coefficients, which can, however, be regularized using consistency conditions between matrix elements out of a single (nonground) state. Similar results hold for suitable "symmetry class" averaged matrix elements where the symmetry class projection operators are "complete." In several cases where the wave functions or projection operators incorporate orthogonal polynomial dependence, we show that the ground state factorization relations have a simplified structure allowing an alternative derivation of the general factorization relations via an infinite matrix inversion procedure. This form is shown to have some advantages over previous versions. In addition, this matrix inversion procedure obtains all consistency conditions (which is not always the case from regularization of singular integrals).
doi:10.1063/1.449401 fatcat:e6x4o4i32ngl7diz7abue7ppde