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Communications in Mathematical Sciences
Volume 19 (2021)
Number 6
Cauchy–Born rule and stability of crystalline solids at finite temperature
Pages: 1461 – 1490
DOI: https://dx.doi.org/10.4310/CMS.2021.v19.n6.a1
Authors
Abstract
We study the connection between atomistic and continuum models for the elastic deformation of crystalline solids at finite temperature. We prove, under certain sharp stability conditions at zero temperature, that the solid is stable when temperature is low. This gives a criterion for the onset of instabilities of crystalline solids as temperature increases. Based on the stability conditions at both zero and finite temperature, we show that the finite temperature version of Cauchy–Born rule gives a correct nonlinear elasticity model in the sense that elastically deformed states of the atomistic model are closely approximated by solutions of the continuum model with free energy functionals obtained from the Cauchy–Born rule at finite temperature. The convergence is proved for both simple and complex lattices.
Keywords
Cauchy–Born rule, finite temperature, stability of crystalline solids, atomistic model
2010 Mathematics Subject Classification
74B20, 74E15, 74G65, 74N99
Received 27 February 2020
Accepted 14 January 2021
Published 2 August 2021