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Philosophical Magazine Volume 94, 2014 - Issue 34
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Part B: Condensed Matter Physics

Decomposition model for phonon thermal conductivity of a monatomic lattice

Alexander V. EvteevUniversity Centre for Mass and Thermal Transport in Engineering Materials, School of Engineering, The University of Newcastle, Callaghan, NSW2308, AustraliaCorrespondence[email protected]
,
Leila MomenzadehUniversity Centre for Mass and Thermal Transport in Engineering Materials, School of Engineering, The University of Newcastle, Callaghan, NSW2308, Australia
,
Elena V. LevchenkoUniversity Centre for Mass and Thermal Transport in Engineering Materials, School of Engineering, The University of Newcastle, Callaghan, NSW2308, Australia
,
Irina V. BelovaUniversity Centre for Mass and Thermal Transport in Engineering Materials, School of Engineering, The University of Newcastle, Callaghan, NSW2308, Australia
&
Graeme E. MurchUniversity Centre for Mass and Thermal Transport in Engineering Materials, School of Engineering, The University of Newcastle, Callaghan, NSW2308, Australia
Pages 3992-4014 | Received 11 Jul 2014, Accepted 19 Sep 2014, Published online: 03 Nov 2014
 
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Abstract

An analytical treatment of decomposition of the phonon thermal conductivity of a crystal with a monatomic unit cell is developed on the basis of a two-stage decay of the heat current autocorrelation function observed in molecular dynamics simulations. It is demonstrated that the contributions from the acoustic short- and long-range phonon modes to the total phonon thermal conductivity can be presented in the form of simple kinetic formulas, consisting of products of the heat capacity and the average relaxation time of the considered phonon modes as well as the square of the average phonon velocity. On the basis of molecular dynamics calculations of the heat current autocorrelation function, this treatment allows for a self-consistent numerical evaluation of the aforementioned variables. In addition, the presented analysis allows, within the Debye approximation, for the identification of the temperature range where classical molecular dynamics simulations can be employed for the prediction of phonon thermal transport properties. As a case example, Cu is considered.

Acknowledgements

This research was supported by the Australian Research Council through its Discovery Project Grants Scheme.

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