DISCRETE-TO-CONTINUUM LINEARIZATION IN ATOMISTIC DYNAMICS

Manuel Friedrich; Manuel Seitz; Ulisse Stefanelli

doi:10.3934/dcds.2024115

DISCRETE-TO-CONTINUUM LINEARIZATION IN ATOMISTIC DYNAMICS

Manuel Friedrich, Manuel Seitz, Ulisse Stefanelli

Department of Mathematics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

In the stationary case, atomistic interaction energies can be proved to Γ-converge to classical elasticity models in the simultaneous atomistic-to-continuum and linearization limit [19, 41]. The aim of this note is that of extending the convergence analysis to the dynamic setting. Moving within the framework of [41], we prove that solutions of the equation of motion driven by atomistic deformation energies converge to the solutions of the momentum equation for the corresponding continuum energy of linearized elasticity. By recasting the evolution problems in their equivalent energy-dissipation-inertia-principle form, we directly argue at the variational level of evolutionary Γ-convergence [33, 37]. This in particular ensures the pointwise in time convergence of the energies.

Original language	English
Pages (from-to)	847-874
Number of pages	28
Journal	Discrete and Continuous Dynamical Systems- Series A
Volume	45
Issue number	3
DOIs	https://doi.org/10.3934/dcds.2024115
Publication status	Published - Mar 2025

Austrian Fields of Science 2012

101002 Analysis

Keywords

Discrete-to-continuum and linearization limit
equation of motion
evolutive Γ-convergence
variational evolution

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abstract = "In the stationary case, atomistic interaction energies can be proved to Γ-converge to classical elasticity models in the simultaneous atomistic-to-continuum and linearization limit [19, 41]. The aim of this note is that of extending the convergence analysis to the dynamic setting. Moving within the framework of [41], we prove that solutions of the equation of motion driven by atomistic deformation energies converge to the solutions of the momentum equation for the corresponding continuum energy of linearized elasticity. By recasting the evolution problems in their equivalent energy-dissipation-inertia-principle form, we directly argue at the variational level of evolutionary Γ-convergence [33, 37]. This in particular ensures the pointwise in time convergence of the energies.",

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author = "Manuel Friedrich and Manuel Seitz and Ulisse Stefanelli",

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AB - In the stationary case, atomistic interaction energies can be proved to Γ-converge to classical elasticity models in the simultaneous atomistic-to-continuum and linearization limit [19, 41]. The aim of this note is that of extending the convergence analysis to the dynamic setting. Moving within the framework of [41], we prove that solutions of the equation of motion driven by atomistic deformation energies converge to the solutions of the momentum equation for the corresponding continuum energy of linearized elasticity. By recasting the evolution problems in their equivalent energy-dissipation-inertia-principle form, we directly argue at the variational level of evolutionary Γ-convergence [33, 37]. This in particular ensures the pointwise in time convergence of the energies.

KW - Discrete-to-continuum and linearization limit

KW - equation of motion

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DISCRETE-TO-CONTINUUM LINEARIZATION IN ATOMISTIC DYNAMICS

Abstract

Austrian Fields of Science 2012

Keywords

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