Thermal conductivity prediction of nanoscale phononic crystal slabs using a hybrid lattice dynamics-continuum mechanics technique

Charles M. Reinke; Mehmet F. Su; Bruce L. Davis; Bongsang Kim; Mahmoud I. Hussein; Zayd C. Leseman; Roy H. Olsson-Iii; Ihab El-Kady

doi:10.1063/1.3675918

Thermal conductivity prediction of nanoscale phononic crystal slabs using a hybrid lattice dynamics-continuum mechanics technique

Charles M. Reinke, Mehmet F. Su, Bruce L. Davis, Bongsang Kim, Mahmoud I. Hussein, Zayd C. Leseman, Roy H. Olsson-Iii, Ihab El-Kady^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

24 Scopus citations

Abstract

Recent work has demonstrated that nanostructuring of a semiconductor material to form a phononic crystal (PnC) can significantly reduce its thermal conductivity. In this paper, we present a classical method that combines atomic-level information with the application of Bloch theory at the continuum level for the prediction of the thermal conductivity of finite-thickness PnCs with unit cells sized in the micron scale. Lattice dynamics calculations are done at the bulk material level, and the plane-wave expansion method is implemented at the macrosale PnC unit cell level. The combination of the lattice dynamics-based and continuum mechanics-based dispersion information is then used in the Callaway-Holland model to calculate the thermal transport properties of the PnC. We demonstrate that this hybrid approach provides both accurate and efficient predictions of the thermal conductivity.

Original language	English
Article number	041403
Journal	AIP Advances
Volume	1
Issue number	4
DOIs	https://doi.org/10.1063/1.3675918
State	Published - Dec 2011
Externally published	Yes

Bibliographical note

Funding Information:
Sandia National Laboratories is a multi-program laboratory managed and operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin Corporation, for the U.S. Department of Energy's National Nuclear Security Administration under contract DE-AC04-94AL85000. BLD and MIH would like to thank Dr. Eduardo A. Misawa and the National Science Foundation for their support under Grant No. CMMI 0927322. ZCL would like to thank the Office of Basic Energy Sciences, Division of Materials Sciences and Engineering under Contract No. DE - FG02 - 10ER46720 (Drs. Kortan and Fitzsimmons), and the National Science Foundation under Grant No. CMMI 1056077 (Dr. Eduardo Misawa).

ASJC Scopus subject areas

General Physics and Astronomy

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10.1063/1.3675918

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title = "Thermal conductivity prediction of nanoscale phononic crystal slabs using a hybrid lattice dynamics-continuum mechanics technique",

abstract = "Recent work has demonstrated that nanostructuring of a semiconductor material to form a phononic crystal (PnC) can significantly reduce its thermal conductivity. In this paper, we present a classical method that combines atomic-level information with the application of Bloch theory at the continuum level for the prediction of the thermal conductivity of finite-thickness PnCs with unit cells sized in the micron scale. Lattice dynamics calculations are done at the bulk material level, and the plane-wave expansion method is implemented at the macrosale PnC unit cell level. The combination of the lattice dynamics-based and continuum mechanics-based dispersion information is then used in the Callaway-Holland model to calculate the thermal transport properties of the PnC. We demonstrate that this hybrid approach provides both accurate and efficient predictions of the thermal conductivity.",

author = "Reinke, \{Charles M.\} and Su, \{Mehmet F.\} and Davis, \{Bruce L.\} and Bongsang Kim and Hussein, \{Mahmoud I.\} and Leseman, \{Zayd C.\} and Olsson-Iii, \{Roy H.\} and Ihab El-Kady",

note = "Funding Information: Sandia National Laboratories is a multi-program laboratory managed and operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin Corporation, for the U.S. Department of Energy's National Nuclear Security Administration under contract DE-AC04-94AL85000. BLD and MIH would like to thank Dr. Eduardo A. Misawa and the National Science Foundation for their support under Grant No. CMMI 0927322. ZCL would like to thank the Office of Basic Energy Sciences, Division of Materials Sciences and Engineering under Contract No. DE - FG02 - 10ER46720 (Drs. Kortan and Fitzsimmons), and the National Science Foundation under Grant No. CMMI 1056077 (Dr. Eduardo Misawa). ",

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doi = "10.1063/1.3675918",

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AU - Reinke, Charles M.

AU - Su, Mehmet F.

AU - Davis, Bruce L.

AU - Kim, Bongsang

AU - Hussein, Mahmoud I.

AU - Leseman, Zayd C.

AU - Olsson-Iii, Roy H.

AU - El-Kady, Ihab

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PY - 2011/12

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N2 - Recent work has demonstrated that nanostructuring of a semiconductor material to form a phononic crystal (PnC) can significantly reduce its thermal conductivity. In this paper, we present a classical method that combines atomic-level information with the application of Bloch theory at the continuum level for the prediction of the thermal conductivity of finite-thickness PnCs with unit cells sized in the micron scale. Lattice dynamics calculations are done at the bulk material level, and the plane-wave expansion method is implemented at the macrosale PnC unit cell level. The combination of the lattice dynamics-based and continuum mechanics-based dispersion information is then used in the Callaway-Holland model to calculate the thermal transport properties of the PnC. We demonstrate that this hybrid approach provides both accurate and efficient predictions of the thermal conductivity.

AB - Recent work has demonstrated that nanostructuring of a semiconductor material to form a phononic crystal (PnC) can significantly reduce its thermal conductivity. In this paper, we present a classical method that combines atomic-level information with the application of Bloch theory at the continuum level for the prediction of the thermal conductivity of finite-thickness PnCs with unit cells sized in the micron scale. Lattice dynamics calculations are done at the bulk material level, and the plane-wave expansion method is implemented at the macrosale PnC unit cell level. The combination of the lattice dynamics-based and continuum mechanics-based dispersion information is then used in the Callaway-Holland model to calculate the thermal transport properties of the PnC. We demonstrate that this hybrid approach provides both accurate and efficient predictions of the thermal conductivity.

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Thermal conductivity prediction of nanoscale phononic crystal slabs using a hybrid lattice dynamics-continuum mechanics technique

Abstract

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