Multiple “time step” Monte Carlo simulations: Application to charged systems with Ewald summation
- 1 July 2004
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 121 (1), 44-50
- https://doi.org/10.1063/1.1755195
Abstract
Recently, we have proposed an efficient scheme for Monte Carlo simulations, the multiple “time step” Monte Carlo (MTS-MC) [J. Chem. Phys. 117, 8203 (2002)] based on the separation of the potential interactions into two additive parts. In this paper, the structural and thermodynamic properties of the simple point charge water model combined with the Ewald sum are compared for the MTS-MC real-/reciprocal-space split of the Ewald summation and the common Metropolis Monte Carlo method. We report a number of observables as a function of CPU time calculated using MC and MTS-MC. The correlation functions indicate that speedups on the order of 4.5–7.5 can be obtained for systems of 108–500 waters for n=10 splitting parameter.Keywords
This publication has 22 references indexed in Scilit:
- Multiple “time step” Monte CarloThe Journal of Chemical Physics, 2002
- Ewald summation techniques in perspective: a surveyComputer Physics Communications, 1996
- A Very Fast Molecular Dynamics Method To Simulate Biomolecular Systems with Realistic Electrostatic InteractionsThe Journal of Physical Chemistry, 1996
- Reversible multiple time scale molecular dynamicsThe Journal of Chemical Physics, 1992
- Cutoff Errors in the Ewald Summation Formulae for Point Charge SystemsMolecular Simulation, 1992
- Molecular dynamics in systems with multiple time scales: Systems with stiff and soft degrees of freedom and with short and long range forcesThe Journal of Chemical Physics, 1991
- Computer Simulation of the Dielectric Properties of Liquid WaterMolecular Simulation, 1989
- Comparison of simple potential functions for simulating liquid waterThe Journal of Chemical Physics, 1983
- P3M3DP—The three-dimensional periodic particle-particle/ particle-mesh programComputer Physics Communications, 1980
- Die Berechnung optischer und elektrostatischer GitterpotentialeAnnalen der Physik, 1921