Issue 6, 2024

Glass-like thermal conductivity and phonon transport mechanism in disordered crystals

Abstract

Solid materials with ultra-low thermal conductivity (κ) are of great interest in thermoelectrics for energy conversion or as thermal barrier coatings for thermal insulation. Many low-κ materials exhibit unique properties, such as weak or even insignificant dependence on temperature (T) for κ, i.e., an anomalous glass-like behavior. However, a comprehensive theoretical model elucidating the microscopic phonon mechanism responsible for the glass-like κT relationship is still absent. Herein, we take rare-earth tantalates (RE3TaO7) as examples to reexamine phonon thermal transport in defective crystals. By combining experimental studies and atomistic simulations up to 1800 K, we revealed that diffusion-like phonons related to inhomogeneous interatomic bonding contribute more than 70% to the total κ, overturning the conventional understanding that low-frequency phonons dominate heat transport. Furthermore, due to the bridging effects of interatomic bonding, the κ of high-entropy tantalates is not necessarily lower than that of medium-entropy materials, suggesting that attempts to reduce κ through high-entropy engineering are limited, at least in defective fluorite tantalates. The new physical mechanism of multimodal phonon thermal transport in defective structures demonstrated in this work provides a reference for the analysis of phonon transport and offers a new strategy to develop and design low-κ materials by regulating the inhomogeneity of interatomic bonding.

Graphical abstract: Glass-like thermal conductivity and phonon transport mechanism in disordered crystals

Supplementary files

Article information

Article type
Communication
Submitted
12 Oct 2023
Accepted
02 Jan 2024
First published
03 Jan 2024

Mater. Horiz., 2024,11, 1567-1578

Glass-like thermal conductivity and phonon transport mechanism in disordered crystals

G. Ren, J. Che, H. Zhang, Y. Yu, W. Hao, Y. Shi, F. Yang and X. Zhao, Mater. Horiz., 2024, 11, 1567 DOI: 10.1039/D3MH01681A

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