Enhancing the thermoelectric performance of Sb1.85In0.15Te3 alloys by effective mass increase via in situ ZnTe formation and resultant Te-excess by Zn addition

IF 4.6 2区物理与天体物理 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

Results in Physics Pub Date : 2025-10-21 DOI:10.1016/j.rinp.2025.108498

Gwan Hyeong Lee , Gyujin Chang , Jaewoo Park , Chanwoo Ju , Yunjae Kim , Seungwoo Ha , Se Yun Kim , Myoung Seok Kwon , Sang-il Kim

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引用次数: 0

Abstract

Sb₂Te₃-based alloys exhibit decent thermoelectric transport properties in mid-temperature range above 550 K, with In-doped Sb₂Te₃ compositions reported to exhibit the higher performance. Doping is known to enhance the thermoelectric efficiency at elevated temperatures by constraining bipolar conduction via bandgap enlargement. In this study, the thermoelectric properties of Sb_1.85In_0.15Te₃ polycrystalline alloys are enhanced by Zn addition, which provides an alternative approach. The in situ formation of ZnTe inclusions during the cooling of nominal Sb_1.85−xIn_0.15Zn_xTe₃ compositions (x = 0, 0.01, 0.02, 0.03, and 0.04) in conventional solid-state reaction induces an excess of Te, which suppresses the intrinsic Te vacancies in Sb_1.85In_0.15Te₃ and thus increases the density-of-state effective mass. Consequently, the power factor increases evenly in the measured temperature range of 300–650 K, reaching 1.17 mW/mK² at 600 K for x = 0.04, representing 19 % improvement over that of the pristine sample. Furthermore, the excess Te and ZnTe inclusions serve as zero- and three-dimensional phonon scattering centers, respectively, effectively reducing lattice thermal conductivity (κ_latt) by effectively scattering both high- and low-frequency phonons. At 300 K, κ_latt of the x = 0.04 sample is 15 % lower than that of the pristine sample, resulting in an enhanced thermoelectric figure of merit, zT, of 0.75 at 600 K, which is 25 % higher than that of pristine Sb_1.85In_0.15Te₃. Since the effective mass increase and lattice thermal conductivity reduction are independent of the known bandgap widening strategies of doping, further enhancement of the thermoelectric efficiency of Sb_1.85In_0.15Te₃ at elevated temperatures can be anticipated through further combined doping.

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通过原位形成ZnTe增加有效质量和添加Zn导致te过量，提高Sb1.85In0.15Te3合金的热电性能

Sb2Te3基合金在550 K以上的中温范围内表现出良好的热电输运性能，其中掺in的Sb2Te3组分表现出更高的性能。众所周知，掺杂可以通过增大带隙来限制双极传导，从而提高高温下的热电效率。在本研究中，添加Zn可以提高Sb1.85In0.15Te3多晶合金的热电性能，这提供了一种替代方法。在常规固相反应中，标称Sb1.85−xIn0.15ZnxTe3成分（x = 0、0.01、0.02、0.03和0.04）冷却过程中，原位形成的ZnTe夹杂物导致Te过量，抑制了Sb1.85 in0.15 te3中固有的Te空位，从而提高了状态有效质量密度。因此，在300-650 K的测量温度范围内，功率因数均匀增加，在600 K时达到1.17 mW/mK2, x = 0.04，比原始样品提高19%。此外，过量的Te和ZnTe夹杂物分别作为零声子和三维声子散射中心，通过有效散射高频和低频声子，有效降低晶格导热系数（κlatt）。在300 K时，x = 0.04样品的kb latt比原始样品的kb latt低15%，导致600 K时热电性能值zT增强，为0.75，比原始Sb1.85In0.15Te3高25%。由于有效质量的增加和晶格热导率的降低与已知的掺杂带隙扩大策略无关，因此可以通过进一步的联合掺杂来进一步提高Sb1.85In0.15Te3在高温下的热电效率。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Results in Physics MATERIALS SCIENCE, MULTIDISCIPLINARYPHYSIC-PHYSICS, MULTIDISCIPLINARY

CiteScore

8.70

自引率

9.40%

发文量

754

审稿时长

50 days

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