Thermal hysteresis and the heat shuttling effect

TL;DR

This paper investigates how hysteresis in phase-change materials affects the heat shuttling effect, revealing that hysteresis can hinder the phenomenon and proposing configurations to enhance its detection.

Contribution

It introduces a thermal model accounting for hysteresis in PCMs and demonstrates its significant impact on heat shuttling, a previously overlooked factor.

Findings

Hysteresis modifies heat shuttling behavior.

Hysteresis can hinder the heat shuttling effect.

Proposed configurations improve observation of heat shuttling.

Abstract

Phononics has attracted much attention driven by the promising potentials offered by devices such as thermal diodes, thermal transistors, and thermal memristors. Heat shuttling (or heat ratcheting, or heat pumping) is a phenomenon exhibited by nonlinear materials presenting temperature-dependent thermal conductivity which, when sandwiched between two thermal baths with one bath subjected to a time-varying temperature, show non vanishing net heat flow, although the baths share the same average temperature. Phase-change materials (PCMs) like VO2 were recently taken for illustration due to a strong change in conductivity over a small temperature range; energy extraction from the thermal variations of the environment was envisioned thereupon. However, up to now, the impact of PCM hysteresis has been overlooked or underestimated. On the basis of a thermal model simulating partial hysteresis loops and non-hysteretic branches, we demonstrate that the presence of hysteresis profoundly modifies the appearance of the heat shuttling effect and can constitute a hindrance to its manifestation. Operating configurations to improve its observation have been proposed.