Achieving high thermoelectric performance through ultra-low lattice thermal conductivity based on phonon localization

IF 38.6 1区材料科学 Q1 CHEMISTRY, PHYSICAL Joule Pub Date : 2024-09-18 DOI:10.1016/j.joule.2024.06.020

Hailong Yang , Baohai Jia , Lin Xie , Dasha Mao , Junchao Xia , Jianmin Yang , Minhui Yuan , Quan Gan , Xusheng Liu , Mingyuan Hu , Jing Shuai , Jiaqing He

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Abstract

Beyond phonon transport, non-propagating transport is also crucial for crystals to achieve ultra-low lattice thermal conductivity (κ_L) approaching the amorphous limitation. In our study, the demonstrated enhancement of phonon localization proves instrumental in achieving ultra-low κ_L, offering an understanding of the role of non-propagating transport. We experimentally verified this principle through a meticulously designed vapor-liquid-solid reaction in Mg₃(Sb,Bi)₂-based materials. A remarkably low κ_L of 0.19 W/mK at room temperature was obtained. This marked a 77% reduction, compared with full-density counterparts, and was attributed to enhanced localization involved in high-frequency phonons. Moreover, we achieved a record zT value close to 1.2 at room temperature, along with the highest average zT value of 1.6 from 300 to 573 K among all n-type materials. These remarkable results align precisely with electron-phonon decoupling through strengthening phonon localization for materials design and application, which underscores the pivotal role in thermal transport.

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基于声子定位的超低晶格热导率实现高热电性能

除了声子传输之外，非传播传输对于晶体实现接近非晶极限的超低晶格热导率（κL）也至关重要。在我们的研究中，声子局域化的增强证明有助于实现超低 κL，从而让我们了解了非传播传输的作用。我们通过在 Mg3(Sb,Bi)2 基材料中精心设计的汽-液-固反应，在实验中验证了这一原理。在室温下，κL 显著降低至 0.19 W/mK。与全密度材料相比，κL 降低了 77%，这归因于高频声子的局域化增强。此外，我们还创下了室温下 zT 值接近 1.2 的记录，并且在所有 n 型材料中，从 300 K 到 573 K 的平均 zT 值最高，达到 1.6。这些非凡的成果与通过加强声子定位实现电子-声子解耦的材料设计和应用不谋而合，凸显了声子在热传输中的关键作用。

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来源期刊

Joule Energy-General Energy

CiteScore

53.10

自引率

2.00%

发文量

198

期刊介绍： Joule is a sister journal to Cell that focuses on research, analysis, and ideas related to sustainable energy. It aims to address the global challenge of the need for more sustainable energy solutions. Joule is a forward-looking journal that bridges disciplines and scales of energy research. It connects researchers and analysts working on scientific, technical, economic, policy, and social challenges related to sustainable energy. The journal covers a wide range of energy research, from fundamental laboratory studies on energy conversion and storage to global-level analysis. Joule aims to highlight and amplify the implications, challenges, and opportunities of novel energy research for different groups in the field.

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