D. E. Angelescu, M. C. Cross, M. L. Roukes
Published 1998-01-23Version 1
Phonon heat transport in mesoscopic systems is investigated using methods analogous to the Landauer description of electrical conductance. A "universal heat conductance" expression that depends on the properties of the conducting pathway only through the mode cutoff frequencies is derived. Corrections due to reflections at the junction between the thermal body and the conducting bridge are found to be small except at very low temperatures where only the lowest few bridge modes are excited. Various non-equilibrium phonon distributions are studied: a narrow band distribution leads to clear steps in the cooling curve, analogous to the quantized resistance values in narrow wires, but a thermal distribution is too broad to show such features.
Comments: To be published in Superlattices and Microstructures, special issue in honor of Rolf Landauer, March 1988
Atomistic simulation of phonon heat transport across metallic nanogaps
Comparison between the two models of dephasing in mesoscopic systems
Intrinsic Decoherence in Mesoscopic Systems
