English

Elastic constants from microscopic strain fluctuations

Condensed Matter 2009-10-31 v2

Abstract

Fluctuations of the instantaneous local Lagrangian strain ϵij(r,t)\epsilon_{ij}(\bf{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 LbL_b) of a system (of total size LL) in the canonical ensemble. Using a simple finite size scaling theory we predict the behaviour of the fluctuations <ϵijϵkl><\epsilon_{ij}\epsilon_{kl}> as a function of Lb/LL_b/L and extract elastic constants of the system {\em 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.

Keywords

Cite

@article{arxiv.cond-mat/9906063,
  title  = {Elastic constants from microscopic strain fluctuations},
  author = {Surajit Sengupta and Peter Nielaba and Madan Rao and K. Binder},
  journal= {arXiv preprint arXiv:cond-mat/9906063},
  year   = {2009}
}

Comments

24 pages REVTEX, 10 .ps figures, version accepted for publication in Physical Review E