# Influence of Boundaries and Thermostatting on Nonequilibrium Molecular   Dynamics Simulations of Heat Conduction in Solids

**Authors:** Zhen Li, Shiyun Xiong, Charles Sievers, Yue Hu, Zheyong Fan, Ning Wei,, Hua Bao, Shunda Chen, Davide Donadio, Tapio Ala-Nissila

arXiv: 1905.11024 · 2020-01-08

## TL;DR

This paper examines how boundary conditions and thermostat choices affect the accuracy of nonequilibrium molecular dynamics simulations of heat conduction in solids, emphasizing the importance of proper temperature profile analysis and thermostat selection.

## Contribution

It demonstrates that nonlinear temperature profiles should be included in thermal transport calculations and shows Langevin thermostats outperform Nosé-Hoover thermostats in nanoscale heat transport simulations.

## Key findings

- Proper thermostat choice affects simulation accuracy.
- Nonlinear temperature profiles are important in calculations.
- Langevin thermostats reduce artifacts in simulations.

## Abstract

Nonequilibrium molecular dynamics (NEMD) has been extensively used to study thermal transport at various length scales in many materials. In this method, two local thermostats at different temperatures are used to generate a nonequilibrium steady state with a constant heat flux. Conventionally, the thermal conductivity of a finite system is calculated as the ratio between the heat flux and the temperature gradient extracted from the linear part of the temperature profile away from the local thermostats. Here we show that, with a proper choice of the thermostat, the nonlinear part of the temperature profile should actually not be excluded in thermal transport calculations. We compare NEMD results against those from the atomistic Green's function method in the ballistic regime, and those from the homogeneous nonequilibrium molecular dynamics method in the ballistic-to-diffusive regime. These comparisons suggest that in all the transport regimes, one should directly calculate the thermal conductance from the temperature difference between the heat source and sink and, if needed, convert it to the thermal conductivity by multiplying it with the system length. Furthermore, we find that the Langevin thermostat outperforms the Nos\'{e}-Hoover (chain) thermostat in NEMD simulations because of its stochastic and local nature. We show that this is particularly important for studying asymmetric carbon-based nanostructures, for which the Nos\'{e}-Hoover thermostat can produce artifacts leading to unphysical thermal rectification. Our findings are important to obtain correct results from molecular dynamics simulations of nanoscale heat transport as the accuracy of the interatomic potentials is rapidly improving.

## Full text

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## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/1905.11024/full.md

## References

74 references — full list in the complete paper: https://tomesphere.com/paper/1905.11024/full.md

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Source: https://tomesphere.com/paper/1905.11024