Reduced basis set expansions for the iodine ion orbitals

## Abstract Optimal orbital exponents are approximated by minimization of the reduced Hamiltonian orbital ground state energy. They appear to be as good as and are obtained at much less expense than the values derived by the usual SCF exponent optimization scheme. Partitioning of energy into 0‐ener

## Abstract To extend the metal cluster size used in interfacing between bulk metals and molecules in __ab initio__ studies of molecular electronics and chemisorption, a reduced size atomic orbital basis set for the gold atom has been generated. Based on the SKBJ relativistic effective core potenti

## Abstract Following the recent studies of basis sets explicitly dependent on oscillatory external electric field we have investigated the possibility of some further truncation of the so‐called polarized basis sets without any major deterioration of the computed data for molecular dipole moments,

## Abstract Formulas are derived for all Hamiltonian integrals required for molecular computations using a novel basis for single‐center expansions. The basis orbitals depend exponentially upon α(__r__ − ρ)^2^ where __r__ and ρ are the distance from center to electron and to a variationally scaled