New method to evaluate atomic electron-repulsion integrals

We recently investigated some features of atomic-electron distributions which are products of atomic orbitals without linear redundancies. Then, the atomic-electron distributions were employed as expansion functions of molecular charge distributions in the three-center expansion method for electron

Following an earlier proposal to evaluate electron repulsion integrals over Gaussian basis functions by a numerical quadrature based on a set of orthogonal polynomials (Rys polynomials), a computational procedure is outlined for efficient evaluation of the two-dimensional integrals Zx, Zy , and I,.

An algorithm for computing electron repulsion integrals ERIs oriented to the general contraction scheme is presented. The accompanying coordinate expansion Ž . ACE method of Ishida is utilized to derive an efficient algorithm. The performance Ž . 2 estimated with the floating-point operation FLOP c

A new systematic way of constructing auxiliary basis functions for approximating the evaluation of electron repulsion integrals is proposed and applied to SCF and MCSCF wavefunction calculations. In the approximation, the one-electron density is expanded in terms of a linear combination of atomic el