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000019591 084__ $$2WoS$$aPhysics, Condensed Matter
000019591 1001_ $$0P:(DE-Juel1)130885$$aPersson, B. N. J.$$b0$$uFZJ
000019591 245__ $$aPhononic heat transfer across an interface: thermal boundary resistance
000019591 260__ $$aBristol$$bIOP Publ.$$c2011
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000019591 440_0 $$03703$$aJournal of Physics: Condensed Matter$$v23$$x0953-8984$$y4
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000019591 500__ $$aWe thank P Avouris, Ch Woll, G Benedek and the authors of [21] for useful communication. BNJP was supported by Invitation Fellowship Programs for Research in Japan from Japan Society of Promotion of Science (JSPS). This work, as part of the European Science Foundation EUROCORES Program FANAS, was supported by funds from the DFG and the EC Sixth Framework Program, under contract ERAS-CT-2003-980409. HU was supported by the Grant-in-Aid for Scientific Research B (No. 21310086) from JSPS. AIV was supported by Russian Foundation for Basic Research (Grant No. 10-02-00297-a) and by DFG.
000019591 520__ $$aWe present a general theory of phononic heat transfer between two solids (or a solid and a fluid) in contact at a flat interface. We present simple analytical results which can be used to estimate the heat transfer coefficient (the inverse of which is usually called the 'thermal boundary resistance' or 'Kapitza resistance'). We present numerical results for the heat transfer across solid-solid and solid-liquid He contacts, and between a membrane (graphene) and a solid substrate (amorphous SiO(2)). The latter system involves the heat transfer between weakly coupled systems, and the calculated value of the heat transfer coefficient is in good agreement with the value deduced from experimental data.
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000019591 7001_ $$0P:(DE-HGF)0$$aVolokitin, A. I.$$b1
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