Long-range forces in molecular dynamics calculations on water

A technique is described for the computer simulation of the motion of 10000 simulated molecr:les. The number of computer operations per time-s:ep is proportional to the number of simuhred particles even though the forcr of interaction may be long range and no force cut-off is employed.

The usefulness of Mulliken nnd Motagn-Kishimoto npproximntions in perrurbntionnl cnlculntions is investigxted. The calculntions are carried out for the hydrogen molecule in its ground and first excited states by n method similar to the Janson-Byors Brown method.

The use of a partial charge version of the Ewald sum method to treat long range electrostatic interactions in molecular dynamics simulations of water has been investigated. The orientational structure and energetic properties of the liquid have been studied for several choices of Ewald sum parameter

## Abstract We describe two algorithms for the parallel calculation of a CHARMm‐like force field in macromolecules. For a molecule with a given number of atoms, we show that there is an optimal number of processors leading to a minimum computation time. At the optimum, both the number of processors

We have used molecular dynamics simulations to study the physical properties of modified TIP3P water model included in the CHARMM program, using four different methods-the Ewald summation technique, and three different spherical truncation methods-for the treatment of the long-range interactions. Bo

Molecular dynamics simulations of pure water employing two different empirical water models have been used to study the effects of different methods for truncation of long-range interactions in molecular mechanics calculations. As has been observed previously in integral equation studies, "shifting"