Achieving High Efficiency in Solution-Processed Perovskite Solar Cells Using C60/C70 Mixed Fullerenes

富勒烯 材料科学 结晶度 能量转换效率 钙钛矿(结构) 化学工程 退火(玻璃) 溶解过程 开路电压 纳米技术 光电子学 复合材料 电压 有机化学 化学 物理 量子力学 工程类
作者
Hao‐Sheng Lin,Il Jeon,Rong Xiang,Seungju Seo,Jin‐Wook Lee,Chao Li,Amrita Pal,Sergei Manzhos,Mark S. Goorsky,Yang Yang,Shigeo Maruyama,Yutaka Matsuo
出处
期刊:ACS Applied Materials & Interfaces [American Chemical Society]
卷期号:10 (46): 39590-39598 被引量:76
标识
DOI:10.1021/acsami.8b11049
摘要

Fullerenes have attracted considerable interest as an electron-transporting layer in perovskite solar cells. Fullerene-based perovskite solar cells produce no hysteresis and do not require high-temperature annealing. However, high power conversion efficiency has been only achieved when the fullerene layer is thermally evaporated, which is an expensive process. In this work, the limitations of a solution-processed fullerene layer have been identified as high crystallinity and the presence of remnant solvents, in contrast to a thermally deposited C60 film, which has low crystallinity and no remaining solvents. As a solution to these problems, a mixed C60 and C70 solution-processed film, which exhibits low crystallinity, is proposed as an electron-transporting layer. The mixed-fullerene-based devices produce power conversion efficiencies as high as that of the thermally evaporated C60-based device (16.7%) owing to improved fill factor and open-circuit voltage. In addition, by vacuum-drying the mixed fullerene film, the power conversion efficiency of the solution-processed perovskite solar cells is further improved to 18.0%. This improvement originates from the enhanced transmittance and charge transport by removing the solvent effect. This simple and low-cost method can be easily used in any type of solar cells with fullerene as the electron-transporting layer.
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