Absorbing boundary conditions for molecular dynamics and multiscale modeling

S. Namilae; D. M. Nicholson; P. K.V.V. Nukala; C. Y. Gao; Y. N. Osetsky; D. J. Keffer

doi:10.1103/PhysRevB.76.144111

Absorbing boundary conditions for molecular dynamics and multiscale modeling

S. Namilae, D. M. Nicholson, P. K.V.V. Nukala, C. Y. Gao, Y. N. Osetsky, D. J. Keffer

Multiscale Modeling & Materials by Desig

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20 Scopus citations

Abstract

We present an application of differential equation based local absorbing boundary conditions to molecular dynamics. The absorbing boundary conditions result in the absorbtion of the majority of waves incident perpendicular to the bounding surface. We demonstrate that boundary conditions developed for the wave equation can be applied to molecular dynamics. Comparisons with damping material boundary conditions are discussed. The concept is extended to the formulation of an atomistic-continuum multiscale scheme with handshaking between the regions based on absorbing boundary conditions. The multiscale model is effective in minimizing spurious reflections at the interface.

Original language	English
Article number	144111
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	76
Issue number	14
DOIs	https://doi.org/10.1103/PhysRevB.76.144111
State	Published - Oct 24 2007

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10.1103/PhysRevB.76.144111

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abstract = "We present an application of differential equation based local absorbing boundary conditions to molecular dynamics. The absorbing boundary conditions result in the absorbtion of the majority of waves incident perpendicular to the bounding surface. We demonstrate that boundary conditions developed for the wave equation can be applied to molecular dynamics. Comparisons with damping material boundary conditions are discussed. The concept is extended to the formulation of an atomistic-continuum multiscale scheme with handshaking between the regions based on absorbing boundary conditions. The multiscale model is effective in minimizing spurious reflections at the interface.",

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AU - Namilae, S.

AU - Nicholson, D. M.

AU - Nukala, P. K.V.V.

AU - Gao, C. Y.

AU - Osetsky, Y. N.

AU - Keffer, D. J.

PY - 2007/10/24

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N2 - We present an application of differential equation based local absorbing boundary conditions to molecular dynamics. The absorbing boundary conditions result in the absorbtion of the majority of waves incident perpendicular to the bounding surface. We demonstrate that boundary conditions developed for the wave equation can be applied to molecular dynamics. Comparisons with damping material boundary conditions are discussed. The concept is extended to the formulation of an atomistic-continuum multiscale scheme with handshaking between the regions based on absorbing boundary conditions. The multiscale model is effective in minimizing spurious reflections at the interface.

AB - We present an application of differential equation based local absorbing boundary conditions to molecular dynamics. The absorbing boundary conditions result in the absorbtion of the majority of waves incident perpendicular to the bounding surface. We demonstrate that boundary conditions developed for the wave equation can be applied to molecular dynamics. Comparisons with damping material boundary conditions are discussed. The concept is extended to the formulation of an atomistic-continuum multiscale scheme with handshaking between the regions based on absorbing boundary conditions. The multiscale model is effective in minimizing spurious reflections at the interface.

UR - https://www.scopus.com/pages/publications/35648942772

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IS - 14

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Absorbing boundary conditions for molecular dynamics and multiscale modeling

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