Additive engineering for Sb2S3 indoor photovoltaics with efficiency exceeding 17%

IF 20.6 Q1 OPTICS
Xiao Chen, Xiaoxuan Shu, Jiacheng Zhou, Lei Wan, Peng Xiao, Yuchen Fu, Junzhi Ye, Yi-Teng Huang, Bin Yan, Dingjiang Xue, Tao Chen, Jiejie Chen, Robert L. Z. Hoye, Ru Zhou
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Abstract

Indoor photovoltaics (IPVs) have attracted increasing attention for sustainably powering Internet of Things (IoT) electronics. Sb2S3 is a promising IPV candidate material with a bandgap of ~1.75 eV, which is near the optimal value for indoor energy harvesting. However, the performance of Sb2S3 solar cells is limited by nonradiative recombination, which is dependent on the quality of the absorber films. Additive engineering is an effective strategy to fine tune the properties of solution-processed films. This work shows that the addition of monoethanolamine (MEA) into the precursor solution allows the nucleation and growth of Sb2S3 films to be controlled, enabling the deposition of high-quality Sb2S3 absorbers with reduced grain boundary density, optimized band positions, and increased carrier concentration. Complemented with computations, it is revealed that the incorporation of MEA leads to a more efficient and energetically favorable deposition for enhanced heterogeneous nucleation on the substrate, which increases the grain size and accelerates the deposition rate of Sb2S3 films. Due to suppressed carrier recombination and improved charge-carrier transport in Sb2S3 absorber films, the MEA-modulated Sb2S3 solar cell yields a power conversion efficiency (PCE) of 7.22% under AM1.5 G illumination, and an IPV PCE of 17.55% under 1000 lux white light emitting diode (WLED) illumination, which is the highest yet reported for Sb2S3 IPVs. Furthermore, we construct high performance large-area Sb2S3 IPV minimodules to power IoT wireless sensors, and realize the long-term continuous recording of environmental parameters under WLED illumination in an office. This work highlights the great prospect of Sb2S3 photovoltaics for indoor energy harvesting.

Abstract Image

效率超过 17% 的 Sb2S3 室内光伏添加工程
室内光伏(IPV)在为物联网(IoT)电子设备持续供电方面吸引了越来越多的关注。Sb2S3 是一种很有前途的 IPV 候选材料,其带隙为 ~1.75 eV,接近室内能量收集的最佳值。然而,Sb2S3 太阳能电池的性能受到非辐射性重组的限制,这取决于吸收薄膜的质量。添加剂工程是微调溶液加工薄膜性能的有效策略。这项研究表明,在前驱体溶液中加入单乙醇胺 (MEA) 可以控制 Sb2S3 薄膜的成核和生长,从而沉积出高质量的 Sb2S3 吸收体,并降低晶界密度、优化带位和提高载流子浓度。计算结果表明,加入 MEA 后,基底上的异质成核沉积效率更高,能量更充足,从而增大了晶粒尺寸,加快了 Sb2S3 薄膜的沉积速率。由于抑制了 Sb2S3 吸收薄膜中的载流子重组并改善了电荷载流子传输,MEA 调制的 Sb2S3 太阳能电池在 AM1.5 G 照明下的功率转换效率 (PCE) 达到了 7.22%,在 1000 勒克斯白光发光二极管 (WLED) 照明下的 IPV PCE 达到了 17.55%,这是目前报道的 Sb2S3 IPV 的最高值。此外,我们还构建了高性能大面积 Sb2S3 IPV 微型模块,为物联网无线传感器供电,并实现了在 WLED 照明下长期连续记录办公室环境参数。这项工作凸显了 Sb2S3 光伏在室内能量收集方面的巨大前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Light-Science & Applications
Light-Science & Applications 数理科学, 物理学I, 光学, 凝聚态物性 II :电子结构、电学、磁学和光学性质, 无机非金属材料, 无机非金属类光电信息与功能材料, 工程与材料, 信息科学, 光学和光电子学, 光学和光电子材料, 非线性光学与量子光学
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2.1 months
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