Multilevel simulation of hard-sphere mixtures

Paul B. Rohrbach; H Kobayashi; Robert Scheichl; Nigel B Wilding; Robert L. Jack

doi:10.48550/arXiv.2206.00974

Multilevel simulation of hard-sphere mixtures

Paul B. Rohrbach^*, H Kobayashi, Robert Scheichl, Nigel B Wilding, Robert L. Jack

^*Corresponding author for this work

School of Physics

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Abstract

We present a multilevel Monte Carlo simulation method for analyzing multi-scale physical systems via a hierarchy of coarse-grained representations, to obtain numerically exact results, at the most detailed level. We apply the method to a mixture of size-asymmetric hard spheres, in the grand canonical ensemble. A three-level version of the method is compared with a previously studied two-level version. The extra level interpolates between the full mixture and a coarse-grained description where only the large particles are present—this is achieved by restricting the small particles to regions close to the large ones. The three-level method improves the performance of the estimator, at fixed computational cost. We analyze the asymptotic variance of the estimator and discuss the mechanisms for the improved performance.

Original language	English
Article number	124109
Journal	The Journal of Chemical Physics
Volume	157
Issue number	12
Early online date	29 Aug 2022
DOIs	https://doi.org/10.48550/arXiv.2206.00974 https://doi.org/10.1063/5.0102875
Publication status	Published - 27 Sept 2022

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title = "Multilevel simulation of hard-sphere mixtures",

abstract = "We present a multilevel Monte Carlo simulation method for analyzing multi-scale physical systems via a hierarchy of coarse-grained representations, to obtain numerically exact results, at the most detailed level. We apply the method to a mixture of size-asymmetric hard spheres, in the grand canonical ensemble. A three-level version of the method is compared with a previously studied two-level version. The extra level interpolates between the full mixture and a coarse-grained description where only the large particles are present—this is achieved by restricting the small particles to regions close to the large ones. The three-level method improves the performance of the estimator, at fixed computational cost. We analyze the asymptotic variance of the estimator and discuss the mechanisms for the improved performance.",

author = "Rohrbach, {Paul B.} and H Kobayashi and Robert Scheichl and Wilding, {Nigel B} and Jack, {Robert L.}",

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AU - Rohrbach, Paul B.

AU - Kobayashi, H

AU - Scheichl, Robert

AU - Wilding, Nigel B

AU - Jack, Robert L.

PY - 2022/9/27

Y1 - 2022/9/27

N2 - We present a multilevel Monte Carlo simulation method for analyzing multi-scale physical systems via a hierarchy of coarse-grained representations, to obtain numerically exact results, at the most detailed level. We apply the method to a mixture of size-asymmetric hard spheres, in the grand canonical ensemble. A three-level version of the method is compared with a previously studied two-level version. The extra level interpolates between the full mixture and a coarse-grained description where only the large particles are present—this is achieved by restricting the small particles to regions close to the large ones. The three-level method improves the performance of the estimator, at fixed computational cost. We analyze the asymptotic variance of the estimator and discuss the mechanisms for the improved performance.

AB - We present a multilevel Monte Carlo simulation method for analyzing multi-scale physical systems via a hierarchy of coarse-grained representations, to obtain numerically exact results, at the most detailed level. We apply the method to a mixture of size-asymmetric hard spheres, in the grand canonical ensemble. A three-level version of the method is compared with a previously studied two-level version. The extra level interpolates between the full mixture and a coarse-grained description where only the large particles are present—this is achieved by restricting the small particles to regions close to the large ones. The three-level method improves the performance of the estimator, at fixed computational cost. We analyze the asymptotic variance of the estimator and discuss the mechanisms for the improved performance.

U2 - 10.48550/arXiv.2206.00974

DO - 10.48550/arXiv.2206.00974

M3 - Article (Academic Journal)

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SN - 0021-9606

VL - 157

JO - The Journal of Chemical Physics

JF - The Journal of Chemical Physics

IS - 12

M1 - 124109

ER -

Multilevel simulation of hard-sphere mixtures

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