热电效应
半导体
化学
单斜晶系
化学物理
无定形固体
凝聚态物理
退火(玻璃)
热电材料
格子(音乐)
热的
热导率
同种类的
相(物质)
塞贝克系数
纳米技术
硫系化合物
随机性
大气温度范围
基质(化学分析)
热力学
材料科学
非晶半导体
带隙
产量(工程)
电子迁移率
晶体缺陷
再结晶(地质)
作者
Yukun Liu,Zhi Li,Debattam Sarkar,Stephanie M. Ribet,Hengdi Zhao,Hongyao Xie,Premakumar Yanda,Juncen Li,Jinfeng Dong,Alfred Yan,C. Shekhar,Qingyu Yan,G. Jeffrey Snyder,M. Grayson,C. Felser,R Palma Dos Reis,Christopher Wolverton,Mercouri G. Kanatzidis,Vinayak P. Dravid
摘要
Medium-entropy semiconductors represent a unique category of entropy-engineered materials. They possess a considerable level of randomness in atomic mixing, although this is not sufficient to conclusively achieve single-phase structure stabilization, in contrast to high-entropy materials. This introduces strong competition between the formation of different phases, which can potentially lead to structural heterogeneity. In this work, we uncover endotaxial nanoprecipitates in the microscopically identified homogeneous medium-entropy semiconductor AgMnSbPbTe 4 . These nanoprecipitates initially crystallize in a cubic phase ( Fm 3̅ m ) within kinetically stabilized AgMnSbPbTe 4, subsequently evolving into a thermodynamically stable monoclinic phase ( P 2 1 / c ) during thermal annealing while maintaining an endotaxial relationship with the matrix lattice. This nanophase segregation and the resultant lattice mismatch at interfaces introduce strain fluctuations up to 5% at intervals of 20 nm across the entire microstructure. Within the matrix phase, atomic displacement of up to 23 pm was observed. This structural heterogeneity results in glass-like thermal transport behavior, achieving an ultralow lattice thermal conductivity κ L = 0.312 Wm –1 K –1 at 800 K, which is in accordance with the amorphous limit predicted by the Cahill model. The synergy of band convergence effect and well-maintained carrier mobility leads to a maximum ZT of 1.72 at 800 K and an average ZT avg of 1.02 over the temperature range of 300–825 K. This study highlights that the underexplored structural heterogeneity in medium-entropy semiconductors can potentially yield beneficial phenomena, such as the phonon-glass electron-crystal transport behavior in this case, which holds promise for advancing thermoelectric applications.
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