Search results for "Interfacial thermal resistance"

showing 2 items of 2 documents

Phonon Bridge Effect in Superlattices of Thermoelectric TiNiSn/HfNiSn With Controlled Interface Intermixing

2020

© 2020 by the authors

Materials scienceIntermixingthin filmthermal boundary resistancePhononGeneral Chemical EngineeringSuperlatticeThermal resistanceCoherent phononintermixing02 engineering and technologyHalf-HeuslerHfNiSnThermal boundary resistancethermoelectric01 natural sciencesArticlelcsh:Chemistrycoherent phonon3 omegaThermal conductivityhalf-Heusler0103 physical sciencesThermoelectric effectInterfacial thermal resistancethermal conductivityGeneral Materials ScienceThin filmThin filmSuperlatticeroughness010302 applied physicsmagnetron sputteringCondensed matter physicsThermoelectricsuperlatticeInterface021001 nanoscience & nanotechnologyThermoelectric materialsRoughnessTiNiSnlcsh:QD1-999Thermal conductivityinterface0210 nano-technology3 omega methodMagnetron sputtering
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Kapitza resistance of laser-annealed surfaces

1984

Our understanding of the phonon processes at the interfaces between two media is still quite rudimentary. Particularly notorious is the helium-solid interface, where the accoustic impedances differ by a large amount. It is well known that the Kapitza resistance, i.e. the thermal boundary resistance between helium and a solid, is usually up to 100 times smaller than predicted by the acoustic theory as formulated by Khalatnikov [1]. However, it was shown by J. WEBER et al. [2] that there was no discrepancy at surfaces of freshly cleaved crystals, i.e. at surfaces of exceptional good quality. Thus it is clear that surface irregularities must be responsible for the anomalous Kapitza resistance.…

Materials scienceQuality (physics)Condensed matter physicschemistrylawPhononRuby laserInterfacial thermal resistancechemistry.chemical_elementddc:530LaserHeliumlaw.invention
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