原子尺度界面强化开启高效耐用的镁基热电器件。

Atomic-scale interface strengthening unlocks efficient and durable Mg-based thermoelectric devices.

作者信息

Zuo Wusheng, Chen Hongyi, Yu Ziyi, Fu Yuntian, Ai Xin, Cheng Yanxiao, Jiang Meng, Wan Shun, Fu Zhengqian, Liu Rui, Cheng Guofeng, Xu Rui, Wang Lianjun, Xu Fangfang, Zhang Qihao, Makarov Denys, Jiang Wan

机构信息

State Key Laboratory of Advanced Fiber Materials, College of Materials Science and Engineering, Donghua University, Shanghai, China.

College of Chemistry and Chemical Engineering, Central South University, Changsha, China.

出版信息

Nat Mater. 2025 May;24(5):735-742. doi: 10.1038/s41563-025-02167-0. Epub 2025 Mar 17.

DOI:10.1038/s41563-025-02167-0

PMID:40097598

Abstract

Solid-state thermoelectric technology presents a compelling solution for converting waste heat into electrical energy. However, its widespread application is hindered by long-term stability issues, particularly at the electrode-thermoelectric material interface. Here we address this challenge by constructing an atomic-scale direct bonding interface. By forming robust chemical bonds between Co and Sb atoms, we develop MgAgSb/Co thermoelectric junctions with a low interfacial resistivity (2.5 µΩ cm), high bonding strength (60.6 MPa) and high thermal stability at 573 K. This thermally stable and ohmic contact interface enables MgAgSb-based thermoelectric modules to achieve a conversion efficiency of 10.2% at a temperature difference of 287 K and to exhibit negligible degradation over 1,440 h of thermal cycling. Our findings underscore the critical role of atomic-scale interface engineering in advancing thermoelectric semiconductor devices, enabling more efficient and durable thermoelectric modules.

摘要

固态热电技术为将废热转化为电能提供了一个极具吸引力的解决方案。然而，其广泛应用受到长期稳定性问题的阻碍，特别是在电极 - 热电材料界面处。在此，我们通过构建原子尺度的直接键合界面来应对这一挑战。通过在Co和Sb原子之间形成稳固的化学键，我们开发出了具有低界面电阻率（2.5 μΩ·cm）、高结合强度（60.6 MPa）以及在573 K下具有高热稳定性的MgAgSb/Co热电结。这种热稳定且呈欧姆接触的界面使基于MgAgSb的热电模块在287 K的温差下实现了10.2%的转换效率，并且在1440小时的热循环中表现出可忽略不计的性能退化。我们的研究结果强调了原子尺度界面工程在推进热电半导体器件发展中的关键作用，能够实现更高效、耐用的热电模块。

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原子尺度界面强化开启高效耐用的镁基热电器件。

Atomic-scale interface strengthening unlocks efficient and durable Mg-based thermoelectric devices.

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