Elastic constants from microscopic strain fluctuations

Abstract

Fluctuations of the instantaneous local Lagrangian strain εij(r,t), measured with respect to a static ``reference'' lattice, are used to obtain accurate estimates of the elastic constants of model solids from atomistic computer simulations. The measured strains are systematically coarse- grained by averaging them within subsystems (of size Lb) of a system (of total size L) in the canonical ensemble. Using a simple finite size scaling theory we predict the behaviour of the fluctuations <εijεkl> as a function of Lb/L and extract elastic constants of the system in the thermodynamic limit at nonzero temperature. Our method is simple to implement, efficient and general enough to be able to handle a wide class of model systems including those with singular potentials without any essential modification. We illustrate the technique by computing isothermal elastic constants of the ``soft'' and the hard disk triangular solids in two dimensions from molecular dynamics and Monte Carlo simulations. We compare our results with those from earlier simulations and density functional theory.

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