Enhanced efficiency of Sb2S3 solar cells via heterojunction interfacial MgCl2-CdCl2 mixed treatment

Yonghao Liu; Hui Deng; Qiqiang Zhu; Changbiao Peng; Yunfeng Lai; Jionghua Wu; Peijie Lin; Weihuang Wang; Shuying Cheng

doi:10.20517/energymater.2025.176

Energy Materials ›› 2026, Vol. 6 ›› Issue (2) :600012 DOI: 10.20517/energymater.2025.176

Article

Enhanced efficiency of Sb₂S₃ solar cells via heterojunction interfacial MgCl₂-CdCl₂ mixed treatment

Author information +

History +

PDF

Abstract

Antimony sulfide (Sb₂S₃) solar cells exhibit significant potential in tandem and indoor photovoltaic applications. The quality of cadmium sulfide (CdS)/Sb₂S₃ heterojunction, affected by energy-level misalignments and lattice-mismatch defects, is crucial for achieving high-performance devices. Herein, we propose a MgCl₂-CdCl₂ mixed treatment strategy for the CdS/Sb₂S₃ interface to suppress interfacial recombination caused by defects and energy band offsets. The obtained preferentially [100]-oriented CdS film effectively mitigates lattice mismatch and induces the subsequent hydrothermal deposition of a well-crystallized, vertically oriented Sb₂S₃ absorber. The MgCl₂-CdCl₂ mixed treatment introduces Mg²⁺ doping in the CdS layer, achieving an enhanced surface potential and well-matched interfacial energy band alignments. The CdS/Sb₂S₃ heterojunction interface forms a spike-type energy band structure with a small conduction band offset. Compared with the conventional CdCl₂ treatment, the MgCl₂-CdCl₂ mixed-treated device exhibits a stronger built-in electric field (1.31 V) and low-temperature activation energy (1.63 eV), indicating the suppression of carrier recombination. Consequently, the champion Sb₂S₃ solar cells achieve an improved efficiency from 7.5% to 8.1%. This heterojunction treatment strategy is expected to provide an effective method for fabricating high-performance inorganic thin film solar cells.

Keywords

Sb₂S₃ solar cells / heterojunction interface / MgCl₂-CdCl₂ mixed-treatment / recombination suppression / efficiency

Cite this article

Download citation ▾

Yonghao Liu, Hui Deng, Qiqiang Zhu, Changbiao Peng, Yunfeng Lai, Jionghua Wu, Peijie Lin, Weihuang Wang, Shuying Cheng. Enhanced efficiency of Sb₂S₃ solar cells via heterojunction interfacial MgCl₂-CdCl₂ mixed treatment. Energy Materials, 2026, 6(2): 600012 DOI:10.20517/energymater.2025.176

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Gu S,Khan F.Recent advances and perspectives on Sb₂S₃ thin-film solar cells.Mater Today Sustain2024;28:101019

[2]	Chen J,Xu Z.Recent Advances and prospects of solution‐processed efficient Sb₂S₃ solar cells.Adv Funct Mater2024;34:2313676

[3]	Chen X,Zhou J.Additive engineering for Sb₂S₃ indoor photovoltaics with efficiency exceeding 17%.Light Sci Appl2024;13:281 PMCID:PMC11447099

[4]	Zheng J,Zhang L.Enhanced hydrothermal heterogeneous deposition with surfactant additives for efficient Sb₂S₃ solar cells.Chem Eng J2022;446:136474

[5]	Zhong M,Liu S.High-performance photodetectors based on Sb₂S₃ nanowires: wavelength dependence and wide temperature range utilization.Nanoscale2017;9:12364-71

[6]	Li S,Shi S,Zhang X.Self-Powered Ultraviolet-Visible-Near infrared broad spectrum Sb₂S₃/TiO₂ photodetectors and The application in emotion detection.Chem Eng J2025;511:161890

[7]	Zhu J,Wang Z.High-performance and stable Sb₂S₃ thin-film photodetectors for potential application in visible light communication.ACS Appl Mater Interfaces2023;15:28175-83

[8]	Shockley W.Detailed balance limit of efficiency of p-n junction solar cells.J Appl Phys1961;32:510-9

[9]	Shen G,Chen S.Strong chelating additive and modified electron transport layer for 8.26%‐efficient Sb₂S₃ solar cells.Adv Energy Mater2025;15:2406051

[10]	Jin X,Salim T.In situ growth of [hk1]‐oriented Sb₂S₃ for solution‐processed planar heterojunction solar cell with 6.4% efficiency.Adv Funct Mater2020;30:2002887

[11]	Li J,Hu X.Manipulating the morphology of CdS/Sb₂S₃ heterojunction using a Mg-doped tin oxide buffer layer for highly efficient solar cells.J Energy Chem2022;66:374-81

[12]	Shah UA,Khalaf GMG,Song H.Wide bandgap Sb₂S₃ solar cells.Adv Funct Mater2021;31:2100265

[13]	Myagmarsereejid P,Batmunkh M.Doping strategies in Sb₂S₃ thin films for solar cells.Small2021;17:2100241

[14]	Deng H,Zhu Q.8.2%-Efficiency hydrothermal Sb₂S₃ thin film solar cells by two-step RTP annealing strategy.Sci China Mater2024;67:3666-74

[15]	Wang Y,Jin M.Full‐dimensional penetration strategy with degradable PEAI enables 8.21% efficiency in bulk heterojunction Sb₂S₃ solar cells.Adv Energy Mater2025;15:2502805

[16]	Chen X,Li C.Interfacial engineering by self‐assembled monolayer for high‐performance Sb₂S₃ solar cells.Adv Energy Mater2024;14:2400441

[17]	Shen B,Dong J.Heterojunction interface anomalous high‐energy level insertion modulating carrier dynamics in high‐efficiency antimony selenide thin‐film solar cells.Adv Funct Mater2025;35:2503922

[18]	Liu R,Zhu L.Space-charging interfacial layer by illumination for efficient Sb₂S₃ bulk-heterojunction solar cells with high open-circuit voltage.ACS Appl Mater Interfaces2023;15:24583-94

[19]	Khallaf H,Lupan O,Park S.Investigation of aluminium and indium in situ doping of chemical bath deposited CdS thin films. J Phys D Appl Phys2008;41:185304

[20]	Cao Z,Ye Z.Anomalous electron doping in CdS to promote the efficiency improvement in Sb₂Se₃ thin film solar cells.Adv Funct Mater2025;35:2418974

[21]	Zhao Y,Jiang C.Regulating energy band alignment via alkaline metal fluoride assisted solution post‐treatment enabling Sb₂(S,Se)₃ solar cells with 10.7% efficiency.Adv Energy Mater2022;12:2103015

[22]	Shen G,Chen S.Interfacial modification strategy by lead chloride post-treatment enables 8.05% efficient Sb₂S₃ solar cells.Nano Research2025;18:94908031

[23]	Cai H,Gao J.Interfacial engineering towards enhanced photovoltaic performance of Sb₂Se₃ solar cell.Adv Funct Mater2022;32:2208243

[24]	Wang L,Qin S.Ambient CdCl₂ treatment on CdS buffer layer for improved performance of Sb₂Se₃ thin film photovoltaics.Appl Phys Lett2015;107:143902

[25]	Su X,Xie Q.Anion-vacancy defect passivation for efficient antimony selenosulfide solar cells via magnesium chloride post-growth activation.Small2025;21:2412322

[26]	Wu W,Wan L.Enhanced performance of close-spaced sublimation processed antimony sulfide solar cells via seed-mediated growth.Adv Sci2024;11:2409312 PMCID:PMC11633527

[27]	Shen LY,Nie ER.Fluorine-doped cds enables oriented growth and defect suppression in Sb₂Se₃ solar cells with high conversion efficiency.Adv Funct Mater2026;36:e15011

[28]	Ishaq M,Mehmood S.Heterojunction interface engineering enabling high transmittance and record efficiency in Sb₂S₃ semitransparent solar cell.Chem Eng J2024;501:157646

[29]	Peng X,He Z.Interfacial bridge bonding enables high‐efficiency Sb₂(S,Se)₃ solar cells with record fill factor exceeding 73%.Adv Funct Mater2025;35:2503314

[30]	Cai JR,Huang WQ.Oxygen-assisted tailoring of evaporated PbS hole transport layer for highly efficient antimony sulfide solar cells.Small2024;21:2407246

[31]	Li H,Cai JR.Solution-processed multivalent molybdenum oxide tailoring band alignment for efficient Sb₂S₃ solar cells.Small2025;21:e07731

[32]	Deng H,Ishaq M.Quasiepitaxy strategy for efficient full‐inorganic Sb₂S₃ solar cells.Adv Funct Mater2019;29:1901720

[33]	Wang G,Huang Y.Boosting efficiency of hydrothermally grown Sb₂S₃ solar cells via rational sulfur engineering.Adv Funct Mater2026;36:e18624

[34]	Mao Y,Hu X.Molten salts assisted interfacial engineering for efficient and low-cost full-inorganic antimony sulfide solar cells.Adv Funct Mater2022;32:2208409