# Elastic Compliance and Stiffness Matrix of the FCC Lennard-Jones Thin   Films: Influence of Thickness and Temperature

**Authors:** J. Puibasset

arXiv: 1903.09435 · 2019-03-25

## TL;DR

This study investigates how the elastic properties of FCC Lennard-Jones thin films vary with thickness and temperature using Monte Carlo simulations, revealing linear relationships and surface effects in stiffness coefficients.

## Contribution

It provides a detailed analysis of elastic compliance and stiffness matrices of Lennard-Jones thin films, highlighting the influence of thickness and temperature on their elastic behavior.

## Key findings

- Poisson's ratios linearly depend on inverse film thickness
- Stiffness coefficients exhibit linearity with inverse thickness
- Surface stiffness components show unexpected out-of-plane features

## Abstract

The fcc Lennard-Jones crystal is used as a generic model of solid to study the elastic properties of thin films as a function of thickness and temperature. The Monte Carlo algorithm is used to calculate the average deformations along the axes in the isostress-isothermal ensemble that mimics a real uniaxial loading experiment. The four independent parameters (tetragonal symmetry The fcc Lennard-Jones crystal is used as a generic model of solid to study the elastic properties of thin films as a function of thickness and temperature. The Monte Carlo algorithm is used to calculate the average deformations along the axes in the isostress-isothermal ensemble that mimics a real uniaxial loading experiment. The four independent parameters (tetragonal symmetry without shear) have been calculated for film thicknesses ranging from 4 to 12 atomic layers, and for five reduced temperatures between 0 and 0.5 sigma/kB, where sigma is the energetic parameter of the Lennard Jones potential and kB is Boltzmann's constant. These parameters (Poisson's ratio and moduli) give the compliance matrix, which is inverted to get the stiffness coefficients. It is shown that the three Poisson's ratios exhibit a good linearity with the inverse of the film thickness, while this is not the case for the moduli and the compliance coefficients. Remarkably, the stiffness coefficients do exhibit a good linearity with the inverse of the film thickness, including the limiting value of infinite thickness (bulk solid) obtained by applying periodic boundary conditions in all directions. This linearity suggests to interpret the results in terms of a bulk+surface decomposition. However, the surface stiffness matrix deduced from the slopes has nonzero components along the out-of-plane direction, an unexpected observation in the framework of the surface stress theory.

---
Source: https://tomesphere.com/paper/1903.09435