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Published April 2014 | public
Journal Article

A meshless quasicontinuum method based on local maximum-entropy interpolation

Abstract

Coarse-graining atomistic ensembles can overcome the practical limitations of molecular statics and dynamics in order to facilitate simulations at much larger length scales than accessible by discrete atomistic techniques due to computational expense. The quasicontinuum (QC) method was introduced to reduce the number of degrees of freedom in crystalline solids by choosing a set of representative atoms from the fully atomistic ensemble and obtaining the positions and momenta of all remaining lattice sites by interpolation. Here, we present a new energy-based nonlocal meshless version of the QC method based on local maximum-entropy (max-ent) interpolation schemes instead of the traditional polynomial interpolation, which particularly promises advantages in model adaptation to tie atomistic resolution to crystal defects while efficiently coarse-graining away from these. To this end, we formulate the meshless QC representation and analyze its performance. One-dimensional chain problems allow for clean mathematical treatment and provide interesting insight, which allow us to quantify the approximation error as a function of representative atom distribution and support of meshless shape functions. A fully three-dimensional implementation then demonstrates the applicability of the new QC scheme and highlights its features. Overall, we show that local max-ent interpolation offers a number of advantages over previous QC realizations.

Additional Information

© 2014 IOP Publishing Ltd. Received 4 September 2013, revised 4 February 2014; Accepted for publication 5 February 2014; Published 1 April 2014. The authors gratefully acknowledge financial support from the US Department of Energy National Nuclear Security Administration (under award number DE-FC52-08NA28613 through Caltech's PSAAP Center for the Predictive Modeling and Simulation of High Energy Density Dynamic Response of Materials).

Additional details

Created:
September 15, 2023
Modified:
October 23, 2023