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Published October 31, 2016 | Published + Submitted
Journal Article Open

Sub-amorphous thermal conductivity in amorphous heterogeneous nanocomposites

Abstract

Pure amorphous solids are traditionally considered to set the lower bound of thermal conductivity due to their disordered atomic structure that impedes vibrational energy transport. However, the lower limits for thermal conductivity in heterogeneous amorphous solids and the physical mechanisms underlying these limits remain unclear. Here, we use equilibrium molecular dynamics to show that an amorphous SiGe nanocomposite can possess thermal conductivity substantially lower than those of the amorphous Si and Ge constituents. Normal mode analysis indicates that the presence of the Ge inclusion localizes vibrational modes with frequency above the Ge cutoff in the Si host, drastically reducing their ability to transport heat. This observation suggests a general route to achieve exceptionally low thermal conductivity in fully dense solids by restricting the vibrational density of states available for transport in heterogeneous amorphous nanocomposites.

Additional Information

© 2016 Royal Society of Chemistry. Received 27 Sep 2016, Accepted 31 Oct 2016, First published online 31 Oct 2016. This work was supported by the Samsung Scholarship, NSF CAREER Award CBET 1254213, and Boeing under Boeing-Caltech Strategic Research and Development Relationship Agreement. This work used the Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by National Science Foundation grant number ACI-1053575. The authors thank Normand Mousseau for providing the atomic positions from the WWW algorithm, and Andrew Robbins, Benoit Latour, Wei Lv, and Asegun Henry for useful discussions.

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Published - c6ra24053d.pdf

Submitted - 1610.00810.pdf

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August 20, 2023
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