Manipulating Anti-Site Defects in α-MgAgSb for Thermoelectric Cooling Enhancement

Juan Li , Guijuan Li , Qiyong Chen , Jianghe Feng , Tao Feng , Lili Xi , Weishu Liu , Wenqing Zhang , Ruiheng Liu , Rong Sun

Interdisciplinary Materials ›› 2025, Vol. 4 ›› Issue (5) : 719 -727.

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Interdisciplinary Materials ›› 2025, Vol. 4 ›› Issue (5) : 719 -727. DOI: 10.1002/idm2.12252
RESEARCH ARTICLE

Manipulating Anti-Site Defects in α-MgAgSb for Thermoelectric Cooling Enhancement

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Abstract

α-MgAgSb is one of the few high-performance thermoelectric materials near room temperature, thanks to its inherently suppressed lattice thermal conductivity. However, conventional approaches to optimizing electrical properties often inadvertently degrade carrier mobility, adversely impacting thermoelectric performance at lower temperatures. In this study, we discovered in an experiment that Mg-Ag anti-site defects exist in the lattice and create staggered nanoscale anti-site zones in the matrix. This unique structure significantly scatters phonons while having a negligible influence on carrier transport due to the preservation of carrier transport channels. By fine-tuning the formation energy of Mg-Ag anti-sites through Zn doping, both carrier transport and phonon scattering were successfully bolstered. Consequently, a high figure of merit (zT) of ~0.45 at 200 K and an average zT of ~0.75 within the low-temperature range of 200-400 K can be achieved. Furthermore, a single-pair device constructed using the obtained α-MgAgSb and commercial Bi2Te3 legs exhibited a temperature difference of ~56 K at 325 K, showcasing promise for thermoelectric cooling applications. This demonstration underscores the efficiency of anti-site manipulation as a means to enhance the thermoelectric cooling performance of α-MgAgSb.

Keywords

α-MgAgSb / anti-site defect / distinctive scatter / thermoelectric cooling

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Juan Li, Guijuan Li, Qiyong Chen, Jianghe Feng, Tao Feng, Lili Xi, Weishu Liu, Wenqing Zhang, Ruiheng Liu, Rong Sun. Manipulating Anti-Site Defects in α-MgAgSb for Thermoelectric Cooling Enhancement. Interdisciplinary Materials, 2025, 4(5): 719-727 DOI:10.1002/idm2.12252

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2025 The Author(s). Interdisciplinary Materials published by Wuhan University of Technology and John Wiley & Sons Australia, Ltd.

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