Comment on analytical calculation of atomic and molecular electrostatic potentials from the poisson equation

An nnnlytic formulation is given for the total potential in atomic and molecular systems, based on the eIectrostatic approach from the Hetlmann-Feynman theorem. The potential function is obtained from the anaIytic solution of the Poisson equation using charge densities expressed as a superposition o

A molecular-orbital study. performed using both multiple scattering Xa and ab uuuo SCF models, is reported for tie 'protonauon process of 02, 0; and O2 The main features of both molecular electrostatic potential and electron deformauon density WUIOUT maps are compared and drscussed.

The PESP Parameterized ElectroStatic P otential method for calculating molecular electrostatic potentials, previously parameterized for H, C, N, O, F, P, S, Cl, and Br, is extended to molecules containing Li q , Na q , Mg 2q , K q , Ca 2q , Zn 2q , and I. For a collection of 166 molecules containing

The shell structure of a selected number of atoms is studied using the average local electrostatic potential function V(r)/p(r) and Gaussian type orbitals. In addition, the influence of electron correlation on this function is discussed: these effects are shown to be small and can be neglected in co

In a recent paper a generalized potential flow theory and its application to the solution of the Navier-Stokes equation are developed.' The purpose of this comment is to show that the analysis presented in that paper is in general not correct. We note that the theoretical development of Reference 1