Stable schemes for dissipative particle dynamics with conserved energy

Stable schemes for dissipative particle dynamics with conserved energy

This article presents a new numerical scheme for the discretization of dissipative particle dynamics with conserved energy. The key idea is to reduce elementary pairwise stochastic dynamics (either fluctuation/dissipation or thermal conduction) to effective single-variable dynamics, and to approxima...

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Veröffentlicht in:Journal of computational physics 2017-07, Vol.340, p.451-469
1. Verfasser: Stoltz, Gabriel
Format: Artikel
Sprache:eng
Schlagworte:
ALGORITHMS
Approximation
APPROXIMATIONS
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
Computational physics
Computer Science
Computer simulation
COMPUTERIZED SIMULATION
Condensed Matter
Dissipation
Dissipative particle dynamics
Dynamic stability
DYNAMICS
Energy conservation
FLUCTUATIONS
HAMILTONIANS
HEAT
MATHEMATICAL SOLUTIONS
Metropolis algorithm
Numerical Analysis
Numerical scheme
PARTICLES
Physics
Simulation
SPECIFIC HEAT
STABILITY
Statistical Mechanics
Stochastic models
STOCHASTIC PROCESSES
THERMAL CONDUCTION
Variables
Variation
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Beschreibung
Zusammenfassung:This article presents a new numerical scheme for the discretization of dissipative particle dynamics with conserved energy. The key idea is to reduce elementary pairwise stochastic dynamics (either fluctuation/dissipation or thermal conduction) to effective single-variable dynamics, and to approximate the solution of these dynamics with one step of a Metropolis–Hastings algorithm. This ensures by construction that no negative internal energies are encountered during the simulation, and hence allows to increase the admissible timesteps to integrate the dynamics, even for systems with small heat capacities. Stability is only limited by the Hamiltonian part of the dynamics, which suggests resorting to multiple timestep strategies where the stochastic part is integrated less frequently than the Hamiltonian one.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2017.03.059