Optimizing Crystal Orientation and Defect Mitigation in Antimony Selenide Thin‐Film Solar Cells through Buffer Layer Energy Band Adjustment

Yang, Yusheng; Zhang, Tingyu; Zhu, Hongcheng; Geng, Kangjun; Huang, Shan; Shen, Bangzhi; Dong, Boning; Zhang, Shuai; Gu, Ding; Jiang, Sai; Yan, Yan; Guo, Huafei; Qiu, Jianhua; Li, LvZhou; Yuan, Ningyi; Ding, Jianning

doi:10.1002/smll.202403292

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2024

DOI: 10.1002/smll.202403292

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Optimizing Crystal Orientation and Defect Mitigation in Antimony Selenide Thin‐Film Solar Cells through Buffer Layer Energy Band Adjustment

Yusheng Yang,

Tingyu Zhang,

Hongcheng Zhu

et al.

Abstract: Antimony selenide (Sb2Se3) has sparked significant interest in high‐efficiency photovoltaic applications due to its advantageous material and optoelectronic properties. In recent years, there has been considerable development in this area. Nonetheless, defects and suboptimal [hk0] crystal orientation expressively limit further device efficiency enhancement. This study used Zinc (Zn) to adjust the interfacial energy band and strengthen carrier transport. For the first time, it is discovered that the diffusion o… Show more

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Regulation of the Charge Carrier Dynamics in Antimony Selenide Thin‐Film Solar Cells Based on the Effective Diffusion of Ions at the Heterojunction Interface

Zhang,

Yang,

Dong

et al. 2024

Adv Funct Materials

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Antimony selenide (Sb2Se3) is regarded as a next‐generation material for high‐efficiency photovoltaic applications due to its favorable bandgap, high absorption coefficient, carrier mobility, and stability. Nonetheless, cadmiun sulfide (CdS) has low short‐wavelength transmittance, which limits photon utilization, and the suboptimal band alignment in the CdS/Sb2Se3 heterojunction causes significant interface recombination. In this study, a simple lithium‐ion doping method is presented and report the dual enhancement effects of lithium ions on CdS and Sb2Se3 layers for the first time. Lithium ions improve the CdS layer by allowing for larger grain sizes, reduces roughness, and increase transmittance in the electron transport layer. At the same time, lightweight Li ions diffuse more easily through the interface into the Sb2Se3 layer, resulting in improved orientation, lower defect density, and a longer carrier lifetime. Furthermore, doping with Li ions changes the band alignment of the CdS/Sb2Se3 junction from a “cliff‐like” to a “spike‐like” configuration, improving carrier transport and reducing carrier recombination near the interface. Ultimately, due to the benefits of Li‐ion doping, the champion device obtained have a VOC of 0.462 V, a JSC of 30.86 mA cm−2, an FF of 65.46%, and an efficiency of 9.33%, representing a 15.8% increase over the undoped device.

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Regulation of the Charge Carrier Dynamics in Antimony Selenide Thin‐Film Solar Cells Based on the Effective Diffusion of Ions at the Heterojunction Interface

Zhang,

Yang,

Dong

et al. 2024

Adv Funct Materials

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show abstract

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Optimizing Crystal Orientation and Defect Mitigation in Antimony Selenide Thin‐Film Solar Cells through Buffer Layer Energy Band Adjustment

Cited by 1 publication

References 53 publications

Regulation of the Charge Carrier Dynamics in Antimony Selenide Thin‐Film Solar Cells Based on the Effective Diffusion of Ions at the Heterojunction Interface

Regulation of the Charge Carrier Dynamics in Antimony Selenide Thin‐Film Solar Cells Based on the Effective Diffusion of Ions at the Heterojunction Interface

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