热电材料
材料科学
纳米技术
热电效应
计算机科学
声子
工程物理
公共记录
锗化合物
测距
作者
Hanhwi Jang,Wooseok Lee,Hwa‐Jung Kim,Sohyang Cha,Hosun Shin,Won Bo Lee,Min‐Wook Oh,Yeon Sik Jung,YongJoo Kim
标识
DOI:10.1002/adma.202515054
摘要
High-entropy alloys are emerging as highly efficient thermoelectrics, but their vast compositional spaces hinder efficient material discovery using conventional heuristics-based and advanced machine learning approaches. Here, this fundamental challenge is addressed by demonstrating an active learning framework that leverages sparse experimental data (80 out of 16206) to efficiently identify three new high-entropy chalcogenides (HECs) with remarkable thermoelectric performance (zT >2). By integrating physics-informed descriptors with uncertainty-aware sampling, this model efficiently assimilates latent structure-property relationships. This allows for systematic exclusion of unfavorable chemistries, enabling even non-experts in thermoelectrics to design unexplored systems with arbitrary components. Furthermore, novel atomic arrangements and distinctive electron and phonon transport properties are uncovered, which are responsible for the superior performance in HECs, advancing the understanding of physical phenomena in disorder-rich systems.
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