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Main Authors: Zhang, Hui, Yue, Jincheng, Zheng, Jiongzhi, Wang, Ning, Ren, Wenling, Lin, Shuyao, Shen, Chen, Gao, Hao, Liu, Yanhui, Fang, Yue-Wen, Cui, Tian
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.16477
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author Zhang, Hui
Yue, Jincheng
Zheng, Jiongzhi
Wang, Ning
Ren, Wenling
Lin, Shuyao
Shen, Chen
Gao, Hao
Liu, Yanhui
Fang, Yue-Wen
Cui, Tian
author_facet Zhang, Hui
Yue, Jincheng
Zheng, Jiongzhi
Wang, Ning
Ren, Wenling
Lin, Shuyao
Shen, Chen
Gao, Hao
Liu, Yanhui
Fang, Yue-Wen
Cui, Tian
contents Defective chalcopyrites have recently emerged as promising thermoelectric materials because their ordered intrinsic vacancies can profoundly reshape both lattice dynamics and electronic structure. Here, we present a comprehensive theoretical investigation of the lattice thermal and carrier transport properties of II-III$_2$-VI$_4$ defective chalcopyrites by combining first-principles calculations with machine-learning interatomic potentials. We show that vacancy ordering enhances lattice distortion, leading to strong anharmonicity and metavalent bonding. The interplay of soft low-frequency phonons, strongly negative Grüneisen parameters, and a substantially enlarged four-phonon scattering phase space results in four-phonon-scattering-dominated heat transport, yielding ultralow lattice thermal conductivity. Meanwhile, systematic anion substitution at the VI-site provides an effective route to tune the electronic structure: reduced anion electronegativity weakens metal-anion hybridization, shifts anion $p$ states upward, narrows the band gap, and thereby improves electrical transport. Benefiting from this synergy between vacancy-induced phonon suppression and anion-regulated electronic optimization, CdGa$_2$Te$_4$ exhibits an ultralow lattice thermal conductivity of 0.19 W$\cdot$m$^{-1}$K$^{-1}$ and a high room-temperature $ZT$ of 0.957. This work not only predicts defective chalcopyrites as a promising platform for high-performance thermoelectrics but also provides a practical design strategy by integrating vacancy ordering, higher-order phonon scattering, and anion-dependent band engineering.
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id arxiv_https___arxiv_org_abs_2603_16477
institution arXiv
publishDate 2026
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spellingShingle Anharmonicity Driven by Vacancy Ordering Unlocks High-performance Thermoelectric Conversion in Defective Chalcopyrites II-III$_2$-VI$_4$
Zhang, Hui
Yue, Jincheng
Zheng, Jiongzhi
Wang, Ning
Ren, Wenling
Lin, Shuyao
Shen, Chen
Gao, Hao
Liu, Yanhui
Fang, Yue-Wen
Cui, Tian
Materials Science
Defective chalcopyrites have recently emerged as promising thermoelectric materials because their ordered intrinsic vacancies can profoundly reshape both lattice dynamics and electronic structure. Here, we present a comprehensive theoretical investigation of the lattice thermal and carrier transport properties of II-III$_2$-VI$_4$ defective chalcopyrites by combining first-principles calculations with machine-learning interatomic potentials. We show that vacancy ordering enhances lattice distortion, leading to strong anharmonicity and metavalent bonding. The interplay of soft low-frequency phonons, strongly negative Grüneisen parameters, and a substantially enlarged four-phonon scattering phase space results in four-phonon-scattering-dominated heat transport, yielding ultralow lattice thermal conductivity. Meanwhile, systematic anion substitution at the VI-site provides an effective route to tune the electronic structure: reduced anion electronegativity weakens metal-anion hybridization, shifts anion $p$ states upward, narrows the band gap, and thereby improves electrical transport. Benefiting from this synergy between vacancy-induced phonon suppression and anion-regulated electronic optimization, CdGa$_2$Te$_4$ exhibits an ultralow lattice thermal conductivity of 0.19 W$\cdot$m$^{-1}$K$^{-1}$ and a high room-temperature $ZT$ of 0.957. This work not only predicts defective chalcopyrites as a promising platform for high-performance thermoelectrics but also provides a practical design strategy by integrating vacancy ordering, higher-order phonon scattering, and anion-dependent band engineering.
title Anharmonicity Driven by Vacancy Ordering Unlocks High-performance Thermoelectric Conversion in Defective Chalcopyrites II-III$_2$-VI$_4$
topic Materials Science
url https://arxiv.org/abs/2603.16477