Augmented chalcopyrites: A search for new Cu-In-Te phases

IF 3.1 3区材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Physical Review Materials Pub Date : 2024-08-26 DOI:10.1103/physrevmaterials.8.083801

Andy Paul Chen, Wei Nong, Maung Thway, Jose Recatala-Gomez, Haiwen Dai, Wenhao Zhai, D. V. Maheswar Repaka, Kedar Hippalgaonkar

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Abstract

Chalcopyrites are ternary crystalline compounds which have found use in a diverse array of applications, from solar cells to thermoelectric devices. These are known to be ternary-compound analogs to diamond or sphalerite. “Defect chalcopyrites,” which are chalcopyrite structures stabilized with ordered vacancies and substitutions, are well attested and can serve as a method of tuning material properties through control of stoichiometry. In particular, defect chalcopyrites related to the thermoelectric compound

{CuInTe}_{2}

comprise a large range of compositions in the pseudobinary system

{({Cu}_{2} Te)}_{x} {({In}_{2} {Te}_{3})}_{1 - x}

, where

x < 0.5

. In contrast, the converse case of “augmented chalcopyrites,” namely,

x > 0.5

, is much less known or studied. We report the discovery of a range of

{Cu}_{2} Te

-rich compositions in this binary system where stable phases can potentially be found. Here, the stoichometry of augmented chalcopyrites is likely to be modulated by the concentration of defect clusters

{[{Cu}_{In}^{2 -} \cdot 2 {Cu}_{i}^{+}]}^{0}

in chalcopyrite

{CuInTe}_{2}

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增生黄铜矿：寻找新的铜锡合金相

黄铜矿是一种三元晶体化合物，已被广泛应用于太阳能电池和热电设备等领域。众所周知，它们是金刚石或闪锌矿的三元化合物类似物。"缺陷黄铜矿 "是一种用有序空位和置换稳定的黄铜矿结构，已得到充分证实，可作为一种通过控制化学计量来调整材料特性的方法。特别是，与热电化合物 CuInTe2 有关的缺陷黄铜矿在假二元系统 (Cu2Te)x(In2Te3)1-x 中包含大量成分，其中 x<0.5.与此相反，人们对 "增强黄铜矿 "的相反情况，即 x>0.5 的了解和研究要少得多。我们报告了在这种二元体系中发现的一系列富含 Cu2Te 的成分，在这些成分中可能存在稳定的相。在这里，增强黄铜矿的稳态测量可能受到黄铜矿 CuInTe2 中缺陷簇 [CuIn2--2Cui+]0 浓度的调节。

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来源期刊

Physical Review Materials Physics and Astronomy-Physics and Astronomy (miscellaneous)

CiteScore

5.80

自引率

5.90%

发文量

611

期刊介绍： Physical Review Materials is a new broad-scope international journal for the multidisciplinary community engaged in research on materials. It is intended to fill a gap in the family of existing Physical Review journals that publish materials research. This field has grown rapidly in recent years and is increasingly being carried out in a way that transcends conventional subject boundaries. The journal was created to provide a common publication and reference source to the expanding community of physicists, materials scientists, chemists, engineers, and researchers in related disciplines that carry out high-quality original research in materials. It will share the same commitment to the high quality expected of all APS publications.