Lone-pair Bi dopants surpass Sb in orbital-defect synergistic regulation for enhanced radiative recombination in AgInS2

IF 7.4 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Science China Materials Pub Date : 2025-09-02 DOI:10.1007/s40843-025-3488-3

Gaoyu Liu (, ), Wenhan Zhou (, ), Yee Sin Ang, Shengli Zhang (, ), Haibo Zeng (, )

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Abstract

AgInS₂, a representative I–III–VI₂ chalcogenide, has garnered significant attention due to its tunable electronic structure, nontoxic nature, and air stability. However, its practical application is hindered by severe nonradiative recombination losses induced by deep-level In_Ag antisite defects, which act as carrier trapping centers. While Sb and Bi doping have been shown to suppress defect states in CuInS₂, their impact on AgInS₂ remains unexplored. This study systematically investigates Sb and Bi doping in AgInS₂ from the perspectives of electronic orbitals interactions and defect regulation. Under S-rich, In-poor, and Ag-moderate conditions, the formation energy of In_Ag defects increases, thereby reducing their concentration. Sb_In and Bi_In emerge as dominant dopant-induced defects, yet they exhibit distinct effects on carrier recombination. Sb doping introduces deep-level states at 1.08 eV below the conduction band minimum through strong Sb–S antibonding interactions, exacerbating nonradiative recombination losses while reducing the radiative recombination coefficient by three orders of magnitude to 1.36×10⁻¹⁶ cm³/s versus intrinsic AgInS₂’s 9.63×10⁻¹³ cm³/s. In contrast, Bi_In defects remain neutral across the Fermi level range, with Bi doping demonstrating superior defect tolerance that effectively suppresses deep-level states and promotes radiative recombination. This enhances the radiative recombination coefficient by one order of magnitude to 1.27×10⁻¹² cm³/s. This study offers critical insights into lone-pair electron effects in Ag-based chalcogenides, contributing to the advancement of sustainable and high-efficiency optoelectronic materials.

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在AgInS2中，单对Bi掺杂物在轨道缺陷协同调控中优于Sb

AgInS2是一种典型的I-III-VI2硫族化合物，由于其可调谐的电子结构、无毒性质和空气稳定性而引起了人们的广泛关注。然而，作为载流子俘获中心的深能级铟银反位缺陷导致的严重的非辐射复合损失阻碍了其实际应用。虽然Sb和Bi掺杂已被证明可以抑制CuInS2中的缺陷态，但它们对AgInS2的影响仍未被探索。本研究从电子轨道相互作用和缺陷调控的角度系统地研究了Sb和Bi在AgInS2中的掺杂。富s、贫in和中银条件下，InAg缺陷的形成能增加，从而降低了其浓度。SbIn和BiIn是掺杂剂诱导的主要缺陷，但它们对载流子重组的影响不同。Sb掺杂通过强烈的Sb - s反键相互作用，在低于导带最小值1.08 eV处引入了深能级态，加剧了非辐射复合损失，同时将辐射复合系数降低了三个数量级，为1.36×10−16 cm3/s，而固有的AgInS2为9.63×10−13 cm3/s。相比之下，BiIn缺陷在费米能级范围内保持中性，Bi掺杂表现出优越的缺陷容忍度，有效抑制了深能级态并促进了辐射重组。这使辐射复合系数提高了一个数量级，达到1.27×10−12 cm3/s。这项研究为银基硫属化合物中的孤对电子效应提供了重要的见解，有助于可持续和高效光电材料的发展。

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来源期刊

Science China Materials Materials Science-General Materials Science

CiteScore

11.40

自引率

7.40%

发文量

949

期刊介绍： Science China Materials (SCM) is a globally peer-reviewed journal that covers all facets of materials science. It is supervised by the Chinese Academy of Sciences and co-sponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China. The journal is jointly published monthly in both printed and electronic forms by Science China Press and Springer. The aim of SCM is to encourage communication of high-quality, innovative research results at the cutting-edge interface of materials science with chemistry, physics, biology, and engineering. It focuses on breakthroughs from around the world and aims to become a world-leading academic journal for materials science.