Atomic to Nanoscale Chemical Fluctuations: The Catalyst for Enhanced Thermoelectric Performance in High-entropy Materials

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2025 Feb 28

PMID 40020070

Authors

Jingyi Wang

Haotian Gao

Kunpeng Zhao

Hexige Wuliji

Binru Zhao

Jie Ma

Xingyu Chen

Jiawei Zhang

Yanping Sui

Tian-Ran Wei

Min Zhu

Xun Shi

Affiliations

Soon will be listed here.

Abstract

High-entropy materials have expanded the frontier for discovering uncharted physicochemical properties. The phenomenon of chemical fluctuation is ubiquitous in high-entropy materials, yet its role in the thermoelectric field is often overlooked. Herein, we designed and synthesized a series of (MgYbSrZn)(MgCdZnNa)(SbCa) samples characterized by ultrahigh configurational entropy. These samples exhibit a homogeneous single-phase structure at macroscopic and microscopic scales, yet display notable chemical fluctuations at the atomic to nanoscale. These fluctuations, along with the unusual atomic occupations, lead to an exceptionally low lattice thermal conductivity akin to that of amorphous materials. Combining the optimized carrier concentration and well-maintained carrier mobility, we ultimately achieved a high value of 1.2 at 750 kelvin, outperforming most previously reported ABSb-type Zintls. This study underscores that the atomic to nanoscale chemical fluctuations are the crucial catalyst for the enhanced thermoelectric performance in high-entropy materials.

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