Solid-State Synthesis and Thermoelectric Properties of CuFeSe₂-CuFeS₂ Solid Solutions.

IF 3.1 3区材料科学 Q3 CHEMISTRY, PHYSICAL

Materials Pub Date : 2025-03-19 DOI:10.3390/ma18061366

Soon-Man Jang, Il-Ho Kim

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Abstract

Thermoelectric technology, which converts heat and electricity into each other, has been attracting attention from the perspective of efficient energy utilization. Recently, eco-friendly and cost-effective Cu-based thermoelectric materials have been actively studied. In particular, efforts have been made to improve thermoelectric properties and enhance performance through the formation of solid solutions. This study examines the formation and thermoelectric properties of Cu-chalcogenide solid solutions between eskebornite (tetragonal CuFeSe₂) and chalcopyrite (tetragonal CuFeS₂), synthesized as CuFeSe_2-yS_y (y = 0-2) using solid-state synthesis. These compounds share similar crystal structures, which enable the formation of solid solutions that enhance phonon scattering and may potentially improve thermoelectric performance. As the S content (y) increased, the lattice parameters a and c decreased, attributed to the smaller ionic radius of S^2- compared to Se^2-, as X-ray diffraction analysis identified single-phase regions for 0 ≤ y ≤ 0.4 and 1.6 ≤ y ≤ 2, respectively. However, for 0.8 ≤ y ≤ 1.2, a composite phase of eskebornite and chalcopyrite formed, indicating incomplete solid solution behavior in the intermediate range. Thermoelectric measurements showed a sharp increase in electrical conductivity with increasing S content, alongside a transition in the Seebeck coefficient from positive (p-type) to negative (n-type), attributed to the intrinsic semiconducting nature of the end-member compounds. Eskebornite behaves as a p-type semiconductor, whereas chalcopyrite is n-type, and their combination affects the carrier type and concentration. Despite these changes, the power factor did not show significant improvement due to the inverse relationship between electrical conductivity and the Seebeck coefficient. The thermal conductivity decreased significantly with solid solution formation, with CuFeSe_0.4S_1.6 exhibiting the lowest value of 0.97 Wm^-1K^-1 at 623 K, a result of enhanced phonon scattering at lattice imperfections and the mass fluctuation effect. This value is lower than the thermal conductivity values of single-phase eskebornite or chalcopyrite. However, the reduction in thermal conductivity was insufficient to compensate for the modest power factor, resulting in no substantial enhancement in the thermoelectric figure of merit.

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CuFeSe2-CuFeS2固溶体的固态合成及热电性能

热电技术是一种热电相互转化的技术，从能源高效利用的角度来看，热电技术一直受到人们的关注。近年来，环保、高性价比的铜基热电材料得到了积极的研究。特别是，人们已经努力通过形成固溶体来改善热电性能和增强性能。本文研究了用固态合成方法合成CuFeSe2- ysy （y = 0-2）的铜硫系固溶体的形成和热电性质。这些化合物具有相似的晶体结构，这使得固体溶液的形成能够增强声子散射，并可能潜在地改善热电性能。随着S含量(y)的增加，晶格参数a和c减小，这是由于与Se2-相比，S2-的离子半径更小，因为x射线衍射分析分别确定了0≤y≤0.4和1.6≤y≤2的单相区。而在0.8≤y≤1.2时，形成一个由钙镁矿和黄铜矿组成的复合相，表明在中间范围内存在不完全的固溶体行为。热电测量表明，随着S含量的增加，电导率急剧增加，同时塞贝克系数从正（p型）转变为负（n型），这归因于端元化合物固有的半导体性质。黄铜矿表现为n型半导体，而黄铜矿表现为p型半导体，两者的组合影响载流子类型和浓度。尽管有这些变化，但由于电导率和塞贝克系数之间的反比关系，功率因数并没有显着改善。随着固溶体的形成，导热系数显著降低，在623 K时CuFeSe0.4S1.6的导热系数最低，为0.97 Wm-1K-1，这是由于晶格缺陷处声子散射增强和质量波动效应的结果。该值低于单相艾氏斑铜矿或黄铜矿的导热系数值。然而，热导率的降低不足以补偿适度的功率因数，导致热电性能没有实质性的提高。

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

Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

5.80

自引率

14.70%

发文量

7753

审稿时长

1.2 months

期刊介绍： Materials (ISSN 1996-1944) is an open access journal of related scientific research and technology development. It publishes reviews, regular research papers (articles) and short communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. Therefore, there is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Materials provides a forum for publishing papers which advance the in-depth understanding of the relationship between the structure, the properties or the functions of all kinds of materials. Chemical syntheses, chemical structures and mechanical, chemical, electronic, magnetic and optical properties and various applications will be considered.