全溶液法无机铯硼铍太阳能电池及其双面辐照功能†。

IF 5 3区 材料科学 Q2 CHEMISTRY, PHYSICAL
Hiroaki Daiguji, Hiroto Takano, Ibuki Watanabe, Rin Ando, Manabu Ishizaki and Masato Kurihara
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引用次数: 0

摘要

虽然实现窗式集成光伏技术需要透光型过氧化物太阳能电池(s-PSCs),但用于(半)透明顶电极的溶液加工技术仍未达到最佳状态。在此,我们选择了一种无机包晶石 CsPbBr3,它是具有波长选择透明度和耐候性的最佳匹配范例,并提出了不含有机成分的最简单 s-PSC,即氟掺杂氧化锡(FTO)/二氧化钛/CsPbBr3/单壁碳纳米管(SWNT)。半透明电极是通过溶液加工的滤波转移 SWNT 薄膜实现的,在 550 纳米波长下具有 60-80%T 的不同透射率。二极管理想系数介于 1 和 2 之间,表明无空穴传输层的 CsPbBr3/SWNT 单二极管模型具有很高的异质结品质。在通过 FTO 的单面伪太阳光照射下,SWNT 增加的导电率(密度)提高了功率转换效率/短路电流,PCEs (FTO)/Jsc = 8.68/7.49 (60) > 8.18/7.33 (70) > 7.30%/6.91 mA cm-2 (80%T)。通过 SWNT,透明度的提高使 PCEs (SWNT)/Jsc 成反比,分别为 4.21/3.79 (60) < 4.45/4.13 (70) < 4.56%/4.56 mA cm-2 (80%T)。通过 FTO 的开路电压/填充因子为 1.48/0.79,通过 SWNT 的开路电压/填充因子为 1.33 V/0.84(60%T)。要实现高性能,必须在导电率和透明度之间做出权衡。使用发光二极管进行双面辐照显示,基于 32-35% 的伪太阳光功率(100 mW cm-2),PCEs(双面)= 3.67 (60)、3.86 (70) 和 3.71% (80%T),相当于单面辐照 PCEs(FTO)和 PCEs(SWNT)的总和。PCEs(双面)与 PCEs(SWNT)/PCEs(FTO)的增强比分别为 3.19/1.36 (60)、3.04/1.46 (70) 和 2.81/1.53 (80%T)。双面功能解决了单面权衡问题。在外部环境下,SWNT 的黑色不会对视觉造成严重影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

All-solution-processed inorganic CsPbBr3 solar cells and their bifacial-irradiation functions†

All-solution-processed inorganic CsPbBr3 solar cells and their bifacial-irradiation functions†

Solution-processed technologies for (semi)transparent top electrodes remain suboptimal, although see-through perovskite solar cells (s-PSCs) are required in realizing window-integrated photovoltaics. Herein, we choose an inorganic perovskite, CsPbBr3, offering the best matching example with wavelength-selective transparency and weatherability, and present the simplest s-PSC excluding organic components, fluorine-doped tin oxide (FTO)/TiO2/CsPbBr3/single-walled carbon nanotube (SWNT). The semitransparent electrode is realized by solution-processed filter-transferred SWNT thin films with different transmittances of 60–80%T at 550 nm. The diode ideal factors range between 1 and 2, suggesting high heterojunction qualities as a single-diode model with hole-transfer-layer-free CsPbBr3/SWNT. Under monofacial pseudo-sunlight irradiation through FTO, the increased electrical conductivities (densities) of SWNT improve power-conversion efficiencies/short-circuit currents, PCEs (FTO)/Jsc = 8.68/7.49 (60) > 8.18/7.33 (70) > 7.30%/6.91 mA cm−2 (80%T). Through SWNT, the increased transparency improves PCEs (SWNT)/Jsc inversely as 4.21/3.79 (60) < 4.45/4.13 (70) < 4.56%/4.56 mA cm−2 (80%T). Open-circuit voltages/fill factors are 1.48/0.79 through FTO and 1.33 V/0.84 through SWNT (60%T). A tradeoff exists between the conductivities and transparency to achieve high performance. Bifacial irradiation using light-emitting diodes shows close values of PCEs (bifacial) = 3.67 (60), 3.86 (70), and 3.71% (80%T) based on 32–35% of pseudo-sunlight power (100 mW cm−2), equivalent to the sums of the monofacial-irradiation PCEs (FTO) and PCEs (SWNT). Enhancement ratios of PCEs (bifacial) to PCEs (SWNT)/to PCEs (FTO) are 3.19/1.36 (60), 3.04/1.46 (70), and 2.81/1.53 (80%T). The bifacial function solves the monofacial tradeoff. The black color of SWNT is not a serious obstacle visually under exterior environments.

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来源期刊
Sustainable Energy & Fuels
Sustainable Energy & Fuels Energy-Energy Engineering and Power Technology
CiteScore
10.00
自引率
3.60%
发文量
394
期刊介绍: Sustainable Energy & Fuels will publish research that contributes to the development of sustainable energy technologies with a particular emphasis on new and next-generation technologies.
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