Thermal Conductance of a metallic dot Single-Electron Transistor

TL;DR

This paper validates a theoretical model of thermal conductance in metallic dot single-electron transistors through experiments, confirming predictions about Coulomb oscillations and demonstrating potential as a heat switch.

Contribution

The study provides the first experimental validation of a theoretical model for thermal conductance in md-SETs, including universal conductance curves and heat-switch operation.

Findings

Perfect agreement between calculated and measured conductances.

Confirmation of Coulomb oscillation periodicity and extreme low-T values.

Demonstration of md-SET as an efficient heat switch.

Abstract

Dots are ideal systems to study fundamentals on heat transfer at the nanoscale and promising nanoscale heat-engines and thermal devices. Here, we report on the validation of our theoretical model on the thermal conductance of a metallic dot single-electron transistor (md-SET) by a recent experiment on the low-T thermal conductance. We compare with the experiment, we emphasize the physics interpretation and characteristic values and we apply the model to evaluate the operation the md-SET as heat-switch. Perfect agreement is shown between the calculated and the measured charge conductance G, heat conductance \k{appa} and the ratio \k{appa}/GT. The experimental findings confirm the theoretical predictions on the periodicity of the Coulomb oscillations in the classical regime, the low-T extreme values and the high-T limits of G and \k{appa}. The calculated conductances of the md-SET are presented in universal curves from low-T to high-T. It is shown that the md-SET can efficiently operate as a heat switch at temperatures , Ec being the charging energy of the dot.