A smooth particle mesh Ewald method
- 15 November 1995
- journal article
- conference paper
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 103 (19) , 8577-8593
- https://doi.org/10.1063/1.470117
Abstract
The previously developed particle mesh Ewald method is reformulated in terms of efficient B‐spline interpolation of the structure factors. This reformulation allows a natural extension of the method to potentials of the form 1/rp with p≥1. Furthermore, efficient calculation of the virial tensor follows. Use of B‐splines in place of Lagrange interpolation leads to analytic gradients as well as a significant improvement in the accuracy. We demonstrate that arbitrary accuracy can be achieved, independent of system size N, at a cost that scales as N log(N). For biomolecular systems with many thousands of atoms this method permits the use of Ewald summation at a computational cost comparable to that of a simple truncation method of 10 Å or less.Keywords
This publication has 55 references indexed in Scilit:
- Molecular dynamics simulation studies of a high resolution Z-DNA crystalThe Journal of Chemical Physics, 1995
- Computer simulation of a phospholipid monolayer-water system: The influence of long range forces on water structure and dynamicsThe Journal of Chemical Physics, 1993
- Computer simulation study of the mean forces between ferrous and ferric ions in waterThe Journal of Physical Chemistry, 1992
- Implementing the fast multipole method in three dimensionsJournal of Statistical Physics, 1991
- A loose-coupling, constant-pressure, molecular dynamics algorithm for use in the modelling of polymer materialsComputer Physics Communications, 1991
- The h = 0 term in Coulomb sums by the Ewald transformationThe Journal of Physical Chemistry, 1990
- An algorithm for the simulation of condensed matter which grows as the 3/2 power of the number of particlesMolecular Physics, 1988
- Molecular dynamics with coupling to an external bathThe Journal of Chemical Physics, 1984
- Comparison of simple potential functions for simulating liquid waterThe Journal of Chemical Physics, 1983
- Electrostatic energy in ionic crystalsProceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 1981