The effect of CO2-doped spiro-OMeTAD hole transport layer on FA(1−x)Cs x PbI3 perovskite solar cells

Z. Fan, Chuwu Xing, Y. Tan, Jinxia Xu, Lingyun Liu, Yuanming Zhou, Yan Jiang
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Abstract

Black-phase formamidinium lead iodine with 1.48 eV bandgap is considered to be the most promising material for improving the near-theoretical limit efficiency of perovskite solar cells, but at room temperature, black-phase formamidinium lead iodine easily transforms into the yellow non-perovskite phase formamidinium lead iodine. Here, different ratios of Cs+-incorporated formamidinium lead iodine prepared by one-step processing with the stability and power conversion efficiency of formamidinium lead iodine perovskite solar cells are investigated. FA0.85Cs0.15PbI3 shows the highest power conversion efficiency of 10.63% (Voc = 1.04 V, Jsc = 16.81 mA cm−2, and fill factor = 0.60), and the unencapsulated device maintained 60% of the initial power conversion efficiency after storage in air with 40% humidity for 186 h with an active area of 0.1 cm2, when the ratios of Cs+ reached 15% (x = 0.15) in formamidinium lead iodine. However, the efficiency of perovskite solar cell–based formamidinium lead iodine is still low. In this work, a simple but an effective strategy was carried out to rapidly and fully oxidize hole transport layer solution by doping CO2 or O2 under ultraviolet light irradiation to increase the conductivity of hole transport layer, thereby improving the power conversion efficiency of solar cells. The results show that FA0.85Cs0.15PbI3 solar cells by CO2-doped hole transport layer for 90 s exhibited the highest power conversion efficiency of 16.11% (VOC = 1.11 V, JSC = 19.73 mA cm−2, and fill factor = 0.74). The improved photovoltaic performance is attributed to CO2-doped spiro-OMeTAD increasing charge carrier density and accelerating charge separation, thereby inducing higher conductivity. CO2 or O2 doped can rapidly and fully oxidize spiro-OMeTAD, and reduce the solar cell fabrication time; it is beneficial to the commercial use of perovskite solar cells.
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co2掺杂spiro-OMeTAD空穴传输层对FA(1−x)Cs x PbI3钙钛矿太阳能电池的影响
带隙为1.48 eV的黑相甲脒铅碘被认为是最有希望提高钙钛矿太阳能电池近理论极限效率的材料,但在室温下,黑相甲脒铅碘很容易转变为黄色非钙钛矿相甲脒铅碘。本文采用一步法制备了不同比例的Cs+掺入量的甲脒铅碘,考察了甲脒铅碘钙钛矿太阳能电池的稳定性和功率转换效率。FA0.85Cs0.15PbI3的最高功率转换效率为10.63% (Voc = 1.04 V, Jsc = 16.81 mA cm−2,填充系数= 0.60),当Cs+在甲醛铅碘中的比例达到15% (x = 0.15)时,未封装器件在40%湿度、0.1 cm2的有效面积下储存186 h后仍保持60%的初始功率转换效率。然而,钙钛矿太阳能电池的效率仍然很低。本研究提出了一种简单而有效的方法,即在紫外光照射下,通过掺杂CO2或O2来快速、充分氧化空穴传输层溶液,从而提高空穴传输层的电导率,从而提高太阳能电池的功率转换效率。结果表明,经co2掺杂空穴传输层制备的FA0.85Cs0.15PbI3太阳能电池的功率转换效率最高,为16.11% (VOC = 1.11 V, JSC = 19.73 mA cm−2,填充因子= 0.74)。由于co2掺杂spiro-OMeTAD增加了载流子密度,加速了电荷分离,从而提高了光电性能。CO2或O2掺杂可以快速、充分地氧化spiro-OMeTAD,缩短太阳能电池的制造时间;这有利于钙钛矿太阳能电池的商业化应用。
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来源期刊
Journal of Chemical Research-s
Journal of Chemical Research-s 化学科学, 有机化学, 有机合成
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期刊介绍: The Journal of Chemical Research is a peer reviewed journal that publishes full-length review and research papers in all branches of experimental chemistry. The journal fills a niche by also publishing short papers, a format which favours particular types of work, e.g. the scope of new reagents or methodology, and the elucidation of the structure of novel compounds. Though welcome, short papers should not result in fragmentation of publication, they should describe a completed piece of work. The Journal is not intended as a vehicle for preliminary publications. The work must meet all the normal criteria for acceptance as regards scientific standards. Papers that contain extensive biological results or material relating to other areas of science may be diverted to more appropriate specialist journals. Areas of coverage include: Organic Chemistry; Inorganic Chemistry; Materials Chemistry; Crystallography; Computational Chemistry.
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