材料科学
热电效应
电介质
相(物质)
大气温度范围
微晶
功勋
凝聚态物理
热电材料
光电子学
热力学
冶金
复合材料
热导率
化学
物理
有机化学
作者
Nan Lin,Shuai Han,Tanmoy Ghosh,Carl‐Friedrich Schön,Dasol Kim,Jonathan Frank,Felix Hoff,T. J. Schmidt,Pingjun Ying,Yuke Zhu,Maria Häser,Minghao Shen,Ming Liu,Jiehe Sui,Oana Cojocaru‐Mirédin,Chongjian Zhou,Ran He,Matthias Wuttig,Yuan Yu
标识
DOI:10.1002/adfm.202315652
摘要
Abstract Monocrystalline SnSe is one of the most promising thermoelectric materials with outstanding performance and a high abundance of constituting elements. However, polycrystalline SnSe, which is more robust for applications, only shows large figure‐of‐merit ( zT ) values in its high‐symmetry phase. Stabilizing the high‐symmetry phase at low temperatures can thus enhance the average zT value over a broad temperature range. In this work, the high‐symmetry rock‐salt SnSe phase is successfully obtained by alloying SnSe with AgVVI 2 compounds (V = Sb, Bi; VI = Se, Te). These cubic SnSe phases show a unique portfolio of properties including a high optical dielectric constant, a large maximum of optical absorption, a large Born effective charge, and abnormal bond‐breaking behavior in laser‐assisted atom probe tomography. All of these characteristics are indicative of metavalent bonding. In contrast, the Pnma phase of SnSe employs covalent bonding. The enhanced symmetry at low temperatures is realized by tailoring chemical bonding. Concomitantly, zT near room temperature is increased by a factor of more than 10 from the pristine Pnma SnSe to Fm m SnSe alloys. This provides insights into the enhancement of the thermoelectric performance of SnSe and other chalcogenides over a broad temperature range by manipulating the chemical bonds.
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