| Literature DB >> 30412411 |
John T Gaskins1, George Kotsonis2, Ashutosh Giri1, Shenghong Ju3,4, Andrew Rohskopf5, Yekan Wang6, Tingyu Bai6, Edward Sachet2, Christopher T Shelton2, Zeyu Liu7, Zhe Cheng5, Brian M Foley5, Samuel Graham5,8, Tengfei Luo7,9, Asegun Henry5,8,10, Mark S Goorsky6, Junichiro Shiomi3,4, Jon-Paul Maria2, Patrick E Hopkins1,11,12.
Abstract
We present experimental measurements of the thermal boundary conductance (TBC) from 78-500 K across isolated heteroepitaxially grown ZnO films on GaN substrates. This data provides an assessment of the underlying assumptions driving phonon gas-based models, such as the diffuse mismatch model (DMM), and atomistic Green's function (AGF) formalisms used to predict TBC. Our measurements, when compared to previous experimental data, suggest that TBC can be influenced by long wavelength, zone center modes in a material on one side of the interface as opposed to the '"vibrational mismatch"' concept assumed in the DMM; this disagreement is pronounced at high temperatures. At room temperature, we measure the ZnO/GaN TBC as 490[+150,-110] MW m-2 K-1. The disagreement among the DMM and AGF, and the experimental data at elevated temperatures, suggests a non-negligible contribution from other types of modes that are not accounted for in the fundamental assumptions of these harmonic based formalisms, which may rely on anharmonicity. Given the high quality of these ZnO/GaN interfaces, these results provide an invaluable, critical, and quantitative assessment of the accuracy of assumptions in the current state of the art computational approaches used to predict phonon TBC across interfaces.Entities:
Keywords: AGF; DMM; Thermal boundary conductance; gallium nitride; interfacial thermal transport; phonon gas model; zinc oxide,
Year: 2018 PMID: 30412411 DOI: 10.1021/acs.nanolett.8b02837
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189