Influence of mass and charge disorder on the phonon thermal conductivity of entropy stabilized oxides determined by molecular dynamics simulations

M. Lim; Zs Rak; J. L. Braun; C. M. Rost; G. N. Kotsonis; P. E. Hopkins; J. P. Maria; D. W. Brenner

doi:10.1063/1.5080419

Influence of mass and charge disorder on the phonon thermal conductivity of entropy stabilized oxides determined by molecular dynamics simulations

M. Lim, Zs Rak, J. L. Braun, C. M. Rost, G. N. Kotsonis, P. E. Hopkins, J. P. Maria, D. W. Brenner

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Abstract

It is shown using classical molecular dynamics simulations that phonon scattering from disorder in the interatomic forces introduced by charge transfer and not from mass disorder is needed to explain the thermal conductivity reduction experimentally measured that accompanies the addition of a sixth cation to the entropy stabilized oxide J14 [(Mg _0.1 Co _0.1 Ni _0.1 Cu _0.1 Zn _0.1 )O _0.5 ]. The simulations were performed on five entropy-stabilized oxides, J14, and J14 plus Sc, Sn, Cr, or Ge in equi-molar cation proportions. Comparing the simulation results to predictions from the Bridgman equation using properties from the simulations suggests that despite phonon scattering from disorder in both atomic forces and mass, the thermal conductivity for these systems is still above an analytical limit for an amorphous structure.

Original language	English (US)
Article number	055105
Journal	Journal of Applied Physics
Volume	125
Issue number	5
DOIs	https://doi.org/10.1063/1.5080419
State	Published - Feb 7 2019

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1063/1.5080419

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title = "Influence of mass and charge disorder on the phonon thermal conductivity of entropy stabilized oxides determined by molecular dynamics simulations",

abstract = " It is shown using classical molecular dynamics simulations that phonon scattering from disorder in the interatomic forces introduced by charge transfer and not from mass disorder is needed to explain the thermal conductivity reduction experimentally measured that accompanies the addition of a sixth cation to the entropy stabilized oxide J14 [(Mg 0.1 Co 0.1 Ni 0.1 Cu 0.1 Zn 0.1 )O 0.5 ]. The simulations were performed on five entropy-stabilized oxides, J14, and J14 plus Sc, Sn, Cr, or Ge in equi-molar cation proportions. Comparing the simulation results to predictions from the Bridgman equation using properties from the simulations suggests that despite phonon scattering from disorder in both atomic forces and mass, the thermal conductivity for these systems is still above an analytical limit for an amorphous structure.",

author = "M. Lim and Zs Rak and Braun, {J. L.} and Rost, {C. M.} and Kotsonis, {G. N.} and Hopkins, {P. E.} and Maria, {J. P.} and Brenner, {D. W.}",

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T1 - Influence of mass and charge disorder on the phonon thermal conductivity of entropy stabilized oxides determined by molecular dynamics simulations

AU - Lim, M.

AU - Rak, Zs

AU - Braun, J. L.

AU - Rost, C. M.

AU - Kotsonis, G. N.

AU - Hopkins, P. E.

AU - Maria, J. P.

AU - Brenner, D. W.

PY - 2019/2/7

Y1 - 2019/2/7

N2 - It is shown using classical molecular dynamics simulations that phonon scattering from disorder in the interatomic forces introduced by charge transfer and not from mass disorder is needed to explain the thermal conductivity reduction experimentally measured that accompanies the addition of a sixth cation to the entropy stabilized oxide J14 [(Mg 0.1 Co 0.1 Ni 0.1 Cu 0.1 Zn 0.1 )O 0.5 ]. The simulations were performed on five entropy-stabilized oxides, J14, and J14 plus Sc, Sn, Cr, or Ge in equi-molar cation proportions. Comparing the simulation results to predictions from the Bridgman equation using properties from the simulations suggests that despite phonon scattering from disorder in both atomic forces and mass, the thermal conductivity for these systems is still above an analytical limit for an amorphous structure.

AB - It is shown using classical molecular dynamics simulations that phonon scattering from disorder in the interatomic forces introduced by charge transfer and not from mass disorder is needed to explain the thermal conductivity reduction experimentally measured that accompanies the addition of a sixth cation to the entropy stabilized oxide J14 [(Mg 0.1 Co 0.1 Ni 0.1 Cu 0.1 Zn 0.1 )O 0.5 ]. The simulations were performed on five entropy-stabilized oxides, J14, and J14 plus Sc, Sn, Cr, or Ge in equi-molar cation proportions. Comparing the simulation results to predictions from the Bridgman equation using properties from the simulations suggests that despite phonon scattering from disorder in both atomic forces and mass, the thermal conductivity for these systems is still above an analytical limit for an amorphous structure.

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Influence of mass and charge disorder on the phonon thermal conductivity of entropy stabilized oxides determined by molecular dynamics simulations

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