On Factorization of Molecular Wavefunctions

Abstract

Recently there has been a renewed interest in the chemical physics literature of factorization of the position representation eigenfunctions \\ of the molecular Schr\"odinger equation as originally proposed by Hunter in the 1970s. The idea is to represent in the form where is purely a function of the nuclear coordinates, while must depend on both electron and nuclear position variables in the problem. This is a generalization of the approximate factorization originally proposed by Born and Oppenheimer, the hope being that an `exact' representation of can be achieved in this form with and interpretable as `electronic' and `nuclear' wavefunctions respectively. We offer a mathematical analysis of these proposals that identifies ambiguities stemming mainly from the singularities in the Coulomb potential energy.