Spatial uniformity as a principle for determination of atomistic structural models

Bin Cai; Andrew L. Goodwin; David A. Drabold

doi:10.1088/0965-0393/19/3/035010

Spatial uniformity as a principle for determination of atomistic structural models

Bin Cai, Andrew L. Goodwin, David A. Drabold

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2 Scopus citations

Abstract

We discuss the concept of structural uniformity as a tool for model construction, and employ the recently proposed reverse Monte Carlo + invariant environment refinement technique (RMC+INVERT) method to create computer models of amorphous materials. We further develop the RMC+INVERT method, and apply it to model glassy GeO₂, by jointly fitting partial pair-correlation functions rather than the total correlation function as in previous calculations. Then the technique was applied to model water-ice (a-H ₂O), for which the uniformity is imposed on the medium range order. For these two cases, we found that imposing spatial uniformity may significantly improve the atomistic model, and the RMC+INVERT method is shown to offer significant advantage over the conventional RMC technique for particular systems.

Original language	English (US)
Article number	035010
Journal	Modelling and Simulation in Materials Science and Engineering
Volume	19
Issue number	3
DOIs	https://doi.org/10.1088/0965-0393/19/3/035010
State	Published - Apr 2011
Externally published	Yes

ASJC Scopus subject areas

Modeling and Simulation
General Materials Science
Condensed Matter Physics
Mechanics of Materials
Computer Science Applications

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10.1088/0965-0393/19/3/035010

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abstract = "We discuss the concept of structural uniformity as a tool for model construction, and employ the recently proposed reverse Monte Carlo + invariant environment refinement technique (RMC+INVERT) method to create computer models of amorphous materials. We further develop the RMC+INVERT method, and apply it to model glassy GeO2, by jointly fitting partial pair-correlation functions rather than the total correlation function as in previous calculations. Then the technique was applied to model water-ice (a-H 2O), for which the uniformity is imposed on the medium range order. For these two cases, we found that imposing spatial uniformity may significantly improve the atomistic model, and the RMC+INVERT method is shown to offer significant advantage over the conventional RMC technique for particular systems.",

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AU - Drabold, David A.

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AB - We discuss the concept of structural uniformity as a tool for model construction, and employ the recently proposed reverse Monte Carlo + invariant environment refinement technique (RMC+INVERT) method to create computer models of amorphous materials. We further develop the RMC+INVERT method, and apply it to model glassy GeO2, by jointly fitting partial pair-correlation functions rather than the total correlation function as in previous calculations. Then the technique was applied to model water-ice (a-H 2O), for which the uniformity is imposed on the medium range order. For these two cases, we found that imposing spatial uniformity may significantly improve the atomistic model, and the RMC+INVERT method is shown to offer significant advantage over the conventional RMC technique for particular systems.

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Spatial uniformity as a principle for determination of atomistic structural models

Abstract

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