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用于高性能染料敏化太阳能电池的高潜力窄带隙豆荚壳天然染料提取物的初步研究。

Preliminary studies on high potential narrow-bandgap pod husk natural dye extracts for high-performance DSSCs.

作者信息

Nbelayim Pascal, Kawamura Go, Kian Tan Wai, Ngubeni Grace, Hasegawa George, Onwona-Agyeman Boateng, Nakanishi Kazuki, Moloto Nosipho, Mubiayi Pierre Kalenga, Matsuda Atsunori

机构信息

Department of Electrical and Electronic Information Engineering, Toyohashi University of Technology 1-1 Hibarigaoka, Tempaku-cho Toyohashi Aichi 441-8580 Japan

Institute of Materials and Systems for Sustainability, Nagoya University Furo-cho, Chikusa-ku Nagoya Aichi 464-8601 Japan +81-527893920.

出版信息

RSC Adv. 2025 Jul 16;15(31):25115-25131. doi: 10.1039/d5ra03406j. eCollection 2025 Jul 15.

DOI:10.1039/d5ra03406j
PMID:40673262
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12264479/
Abstract

The urgent global transition away from fossil fuels, driven by climate change mitigation, rising energy demands, and exponential growth of high-energy-consuming AI technology, calls for every available sustainable renewable energy solution. DSSCs emerge as promising photovoltaics due to their cost-effectiveness, efficiency in low-light conditions, versatility, and aesthetic appeal. A crucial avenue for enhancing DSSC sustainability lies in utilizing natural dyes as sensitizers. This study explores novel natural dye extracts from the pod husk of , employing seven different solvents to investigate their photovoltaic potential. Some extracts exhibit exceptional light absorbance with band gaps ranging 1.82-2.85 eV-comparable to the high-performing synthetic N719 dye (1.75 eV). These performances surpass typical natural dyes with band gaps ≥2.0 eV. Photovoltaic performance assessments yielded efficiencies between 0.07-0.19%, within the reported range of natural dye DSSCs (0.05-4.2%; usually of high purity or combinations), though significantly lower than N719 (6.22%). Photoanode thickness reduction from 8 to 5 μm enhanced efficiencies to 0.09-0.24% (compared to 4.20% for N719), yet fell below anticipated values based on strong optical absorption. Subsequent characterizations-TG-DTA, IPCE, PL, EIS, FT-IR, and CV-identified two primary limiting factors: high series and ion diffusion resistances, attributed to inefficient band alignments with TiO and the I /I electrolyte, and dye degradation. Optimizing DSSC architecture through appropriate semiconductor materials and redox electrolytes could significantly improve these natural dyes performances. This work advances the potential for cost-effective, eco-friendly, high-performance DSSCs and contributes to groundwork for future advancements in sustainable solar energy.

摘要

由于减缓气候变化、能源需求不断上升以及高能耗人工智能技术呈指数级增长,全球迫切需要从化石燃料转向可持续可再生能源解决方案。染料敏化太阳能电池(DSSC)因其成本效益、低光照条件下的效率、多功能性和美观性而成为有前景的光伏技术。提高DSSC可持续性的一个关键途径是使用天然染料作为敏化剂。本研究探索了从[具体植物]的豆荚壳中提取的新型天然染料,使用七种不同的溶剂来研究它们的光伏潜力。一些提取物表现出优异的光吸收性能,带隙范围为1.82 - 2.85电子伏特,与高性能合成N719染料(1.75电子伏特)相当。这些性能超过了带隙≥2.0电子伏特的典型天然染料。光伏性能评估得出的效率在0.07 - 0.19%之间,处于天然染料DSSC报道的范围内(0.05 - 4.2%;通常为高纯度或组合),但明显低于N719(6.22%)。光阳极厚度从8微米减小到5微米,效率提高到0.09 - 0.24%(相比之下,N719为4.20%),但仍低于基于强光学吸收预期的值。随后的表征——热重-差示热分析(TG-DTA)、入射光电流转换效率(IPCE)、光致发光(PL)、电化学阻抗谱(EIS)、傅里叶变换红外光谱(FT-IR)和循环伏安法(CV)——确定了两个主要限制因素:高串联电阻和离子扩散电阻,这归因于与二氧化钛(TiO)和I /I电解质的能带排列效率低下以及染料降解。通过适当的半导体材料和氧化还原电解质优化DSSC结构可以显著提高这些天然染料的性能。这项工作提升了具有成本效益、环保、高性能DSSC的潜力,并为可持续太阳能未来发展奠定了基础。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/66f7/12264479/626f442877dc/d5ra03406j-f8.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/66f7/12264479/626f442877dc/d5ra03406j-f8.jpg
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