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Paper detail

Modeling interfacial phonon transport with normal mode dynamics

Traditional theories of interfacial heat transfer by atomic vibrations, also known as phonons, do not explain how vibrational mode interactions contribute to interface conductance. Traditional methods also use the concept of phonons as particles or waves which propagate and transmit energy through interfaces; such methods are therefore inapplicable to realistic non-crystalline systems where phonons are not propagating. Here we introduce a more general formalism of interfacial phonon transport, rigorously derived from interatomic interactions projected onto the normal modes of the system, showing for the first time how interactions between vibrational modes contribute to thermal interface conductance. This new physical picture is based on the concept of forces and energy exchange between modes, regardless of their propagating or non-propagating character, thus providing a general formalism to describe phonon transport in all solids regardless of disorder.

preprint2021arXivOpen access
Andrew Rohskopf
cond-mat.mtrl-sci
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Andrew Rohskopf

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