Effect of air confinement on thermal contact resistance in nanoscale heat transfer

TL;DR

This study investigates how air pressure affects thermal contact resistance at the nanoscale between a Wollaston wire probe and samples, revealing increased heat transfer with pressure and proposing an analytical model validated by experimental data.

Contribution

It introduces a new analytical model for thermal contact resistance that accounts for air pressure effects at the nanoscale, validated by experimental measurements.

Findings

Thermal contact resistance decreases with increasing air pressure.

Heat transfer increases with air pressure and is higher for more thermally conductive materials.

The analytical model accurately predicts Rc values in the experimental range.

Abstract

We report herein the pressure dependent thermal contact resistance (Rc) between Wollaston wire thermal probe and samples which is evaluated within the framework of an analytical model. This work presents heat transfer between the Wollaston wire thermal probe and samples at nanoscale for different air pressure ranging from 1 Pa to 10e5 Pa. We make use of a scanning thermal microscopy (SThM) for the thermal analysis of two samples, fused silica (SiO2) and Titanium (Ti), with different thermal conductivities. The thermal probe's output voltage difference (deltaV) between out-off contact output voltage (Voc) and in-contact output voltage (Vic) was recorded. The result shows that the heat transfer increases with the increasing air pressure and it is found higher for higher thermal conductive material. We also propose an analytical model based on the normalized output voltage difference to extract the probe-sample thermal contact resistance. The obtained Rc values in the range of ~1.8e7 K/W to ~14.3e7 K/W validate the presented analytical model. Further analysis reveals that the thermal contact resistance between the probe and sample decreases with increasing air pressure. Such behavior is interpreted by the contribution of heat transfer through confined air on thermal contact resistance. In addition, the signature of Rc is also evidenced in the context of thermal mismatch behavior which is studied by using acoustic mismatch model (AMM) and diffuse mismatch model (DMM).