热电效应
声子
纳米尺度
材料科学
热电材料
热导率
合金
散射
塞贝克系数
热的
微观结构
载流子
纳米技术
凝聚态物理
格子(音乐)
热涨落
电阻率和电导率
电荷(物理)
光电子学
晶体管
声子散射
热传导
微尺度化学
灵活性(工程)
纳米-
化学物理
数码产品
工程物理
电导率
纳米线
作者
Yuxiang Zhan,Kunpeng Zhao,Hexige Wuliji,Yifan Yuan,Xiang Liu,Tian‐Ran Wei,Ting Zhang,Min Zhu,Xun Shi
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-03-25
卷期号:12 (13): eaec0728-eaec0728
标识
DOI:10.1126/sciadv.aec0728
摘要
(Ag,Cu)2(S,Se,Te) alloys, as rare examples of p-type inorganic ductile semiconductors, have emerged as promising candidates for wearable electronics because of their mechanical flexibility and favorable processability. However, the multicomponent nature of this system introduces diverse microstructures and intricate defect landscapes that complicate the optimization of thermoelectric performance. Here, we reveal the presence of compositionally inhomogeneous yet structurally coherent nanoscale chemical fluctuations within this alloy system. These fluctuations, together with abundant dislocations and twin boundaries, serve as efficient phonon scattering centers to suppress the lattice thermal conductivity to approach glass-like levels. Concurrently, tuning the cation ratios and vacancies allows for precise control over the carrier concentration and thereby leads to enhanced power factors. Last, a peak zT of 0.98 at 360 kelvins is achieved, marking a record for Ag-based ductile thermoelectrics. This study highlights the essential role of chemical fluctuations in modulating phonon and charge transports and offers valuable insight into the microstructure-defect-property interplay in ductile materials.
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