Scalable monolayer-functionalized nanointerface for thermal conductivity enhancement in copper/diamond composite

Aiming at developing high thermal conductivity copper/diamond composite, an unconventional approach applying self-assembled monolayer (SAM) prior to the high-temperature sintering of copper/diamond composite was utilized to enhance the thermal boundary conductance (TBC) between copper and diamond. T...

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Veröffentlicht in:	arXiv.org 2021-01
Hauptverfasser:	Xu, Bin, Shih-Wei, Hung, Hu, Shiqian, Shao, Cheng, Guo, Rulei, Choi, Junho, Kodama, Takashi, Fu-Rong, Chen, Shiomi, Junichiro
Format:	Artikel
Sprache:	eng
Schlagworte:	Composite materials Copper Diamonds Heat conductivity Heat transfer High temperature Molecular dynamics Monolayers Morphology Physics - Materials Science Resistance Room temperature Self-assembled monolayers Self-assembly Thermal conductivity
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creator	Xu, Bin Shih-Wei, Hung Hu, Shiqian Shao, Cheng Guo, Rulei Choi, Junho Kodama, Takashi Fu-Rong, Chen Shiomi, Junichiro
description	Aiming at developing high thermal conductivity copper/diamond composite, an unconventional approach applying self-assembled monolayer (SAM) prior to the high-temperature sintering of copper/diamond composite was utilized to enhance the thermal boundary conductance (TBC) between copper and diamond. The enhancement was first systematically confirmed on a model interface system by detailed SAM morphology characterization and TBC measurements. TBC significantly depends on the SAM coverage and ordering, and the formation of high-quality SAM promoted the TBC to 73 MW/m^2-K from 27 MW/m^2-K, the value without SAM. With the help of molecular dynamics simulations, the TBC enhancement was identified to be determined by the number of SAM bridges and the overlap of vibrational density of states. The diamond particles of 210 {\micro\metre} in size were simultaneously functionalized by SAM with the condition giving the highest TBC in the model system and sintered together with the copper to fabricate isotropic copper/diamond composite of 50% volume fraction. The measured thermal conductivity marked 711 W/m-K at room temperature, the highest value among the ones with similar diamond-particles volume fraction and size. This work demonstrates a novel strategy to enhance the thermal conductivity of composite materials by SAM functionalization.
doi_str_mv	10.48550/arxiv.2101.01396
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subjects	Composite materials Copper Diamonds Heat conductivity Heat transfer High temperature Molecular dynamics Monolayers Morphology Physics - Materials Science Resistance Room temperature Self-assembled monolayers Self-assembly Thermal conductivity
title	Scalable monolayer-functionalized nanointerface for thermal conductivity enhancement in copper/diamond composite
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