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Heat Transfer across the Interface between Nanoscale Solids and Gas
ABSTRACT: When solid materials and devices
scale down in size, heat transfer from the active region to the gas environment
becomes increasingly significant. We show that the heat transfer coefficient
across the solid – gas interface behaves very differently when the size of the
solid is reduced to the nanoscale, such as that of a single nanowire. Unlike for
macroscopic solids, the coefficient is strongly pressure dependent above ~ 10
torr, and at lower pressures it is much higher than predictions of the kinetic
gas theory. The heat transfer coefficient was measured between a single,
free-standing VO2 nanowire and surrounding air using laser thermography, where
the temperature distribution along the VO2 nanowire was determined by imaging
its domain structure of metal-insulator phase transition. The one-dimensional
domain structure along the nanowire results from the balance between heat
generation by the focused laser and heat dissipation to the substrate as well as
to the surrounding gas, and thus serves as a nanoscale power-meter and
thermometer. We quantified the heat loss rate across the nanowire-air interface,
and found that it dominates over all other heat dissipation channels for
small-diameter nanowires near ambient pressure. As the heat transfer across the
solid – gas interface is nearly independent of the chemical identity of the
solid, the results reveal a general scaling relationship for gaseous heat
dissipation from nanostructures of all solid materials, which is applicable to
nanoscale electronic and thermal devices exposed to gaseous environments.
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