材料科学
空位缺陷
晶体缺陷
凝聚态物理
声子
热电效应
格子(音乐)
位错
热电材料
晶界
瓶颈
攀登
塞贝克系数
电子
控制重构
电子迁移率
联轴节(管道)
晶体管
工程物理
完美水晶
热导率
对称(几何)
拓扑缺陷
热的
统计物理学
弗伦克尔缺陷
渡线
纳米技术
耦合强度
作者
Yang Zhang,Yang Zhang,Ye Yang,Guyang Peng,Tong Song,Rongrong Li,Wanbo Qu,Kangjin Zhou,Tianle Xie,Chaoliang Zhang,Kun Wang,Zhihao Zhao,Yi-Xiang Wang,Xianghong Zhou,Yuetao Zhang,Yuetao Zhang,Yushan Guo,Yihua Zhang,Yihua Zhang,Xingwu Zou
标识
DOI:10.1002/adma.202520643
摘要
) and carrier mobility (µ) remains the central bottleneck in thermoelectric optimization: randomly distributed defects that scatter phonons inevitably degrade electron transport. This review establishes the disorder-to-order transition of crystallographic defects as a unifying design principle to overcome this trade-off. We systematically examine three defect families, including substitutional atoms, vacancies, interstitials and antisite defects demonstrate how their spatial reconfiguration from random distributions into ordered architectures fundamentally decouples phonon and electron transport. Representative examples include iso-size alloying and symmetry enhancement in substitutional systems, vacancy-derived dislocation networks and ordered vacancy layers, lattice planarization via targeted vacancy filling, and self-assembled interstitial clusters and climb dislocations. We further extend this paradigm into the mechanical domain, showing that ordered interstitials at twin boundaries simultaneously enhance mechanical strength and thermoelectric performance. A consistent conclusion emerges across all systems: performance gains arise from controlling defect spatial arrangement rather than introducing additional disorder, offering a coherent framework for the next generation of high-performance, mechanically robust thermoelectric materials.
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