Advances on Sb2Se3 Solar Cells Fabricated by Physical Vapor Deposition Techniques

Pub Date : 2023-10-12 DOI:10.3390/solar3040031
Roberto Jakomin, Stefano Rampino, Giulia Spaggiari, Francesco Pattini
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Abstract

Sb2Se3, as an earth-abundant and low-toxic material, has emerged as one of the most interesting absorbers for clean renewable power generation technologies. Due to its optical properties, especially bandgap and absorption coefficient, the number of papers on Sb2Se3-based solar cells has been constantly increasing in the last ten years, and its power conversion efficiency has raised from 1% in 2014 to 10.57% in 2022. In this review, different Sb2Se3 solar cells’ fabrication technologies based on physical vapor deposition are described and correlated to the texture coefficient (ribbon orientation). Moreover, recent research works of the most promising solar cell configurations with different electron-transporting layers and hole-transporting layers are analyzed with a special emphasis on photovoltaic performances. Furthermore, different Sb2Se3 doping techniques are discussed. All these aspects are considered as new strategies to overcome the Sb2Se3 solar cell’s actual limitations.
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物理气相沉积技术制备Sb2Se3太阳能电池的研究进展
Sb2Se3作为一种储量丰富的低毒材料,已成为清洁可再生能源发电技术中最有趣的吸收剂之一。由于其光学特性,特别是带隙和吸收系数,sb2se3基太阳能电池的论文数量在过去十年中不断增加,其功率转换效率从2014年的1%提高到2022年的10.57%。本文综述了基于物理气相沉积的不同Sb2Se3太阳能电池的制备技术,并将其与织构系数(带状取向)进行了比较。此外,对具有不同电子输运层和空穴输运层的太阳能电池结构的最新研究工作进行了分析,并特别强调了光伏性能。此外,还讨论了不同的Sb2Se3掺杂技术。这些都被认为是克服Sb2Se3太阳能电池实际局限性的新策略。
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