Influence of thermostatting on nonequilibrium molecular dynamics simulations of heat conduction in solids
No Thumbnail Available
Access rights
openAccess
Journal Title
Journal ISSN
Volume Title
A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä
This publication is imported from Aalto University research portal.
View publication in the Research portal
View/Open full text file from the Research portal
Other link related to publication
View publication in the Research portal
View/Open full text file from the Research portal
Other link related to publication
Date
2019-12-21
Department
Major/Subject
Mcode
Degree programme
Language
en
Pages
Series
Journal of Chemical Physics, Volume 151, issue 23
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 into the thermal conductivity by multiplying it with the system length. Furthermore, we find that the Langevin thermostat outperforms the Nosé-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 Nosé-Hoover thermostat can produce artifacts leading to unphysical thermal rectification.Description
Keywords
Other note
Citation
Li, Z, Xiong, S, Sievers, C, Hu, Y, Fan, Z, Wei, N, Bao, H, Chen, S, Donadio, D & Ala-Nissila, T 2019, ' Influence of thermostatting on nonequilibrium molecular dynamics simulations of heat conduction in solids ', Journal of Chemical Physics, vol. 151, no. 23, 234105 . https://doi.org/10.1063/1.5132543