Multifunctional Enhancement for Highly Stable and Efficient Perovskite Solar Cells

材料科学 钝化 钙钛矿(结构) 结晶 载流子寿命 光电子学 纳米技术 能量转换效率 兴奋剂 碘化物 水分 化学工程 无机化学 复合材料 图层(电子) 化学 工程类
作者
Yuan Cai,Jian Cui,Ming Chen,Miaomiao Zhang,Yu Han,Qian Fang,Huan Zhao,Shaomin Yang,Zhou Yang,Hongtao Bian,Tao Wang,Kunpeng Guo,Molang Cai,Songyuan Dai,Zhike Liu,Shengzhong Liu
出处
期刊:Advanced Functional Materials [Wiley]
卷期号:31 (7) 被引量:413
标识
DOI:10.1002/adfm.202005776
摘要

Abstract With a certified efficiency as high as 25.2%, perovskite has taken the crown as the highest efficiency thin film solar cell material. Unfortunately, serious instability issues must be resolved before perovskite solar cells (PSCs) are commercialized. Aided by theoretical calculation, an appropriate multifunctional molecule, 2,2‐difluoropropanediamide (DFPDA), is selected to ameliorate all the instability issues. Specifically, the carbonyl groups in DFPDA form chemical bonds with Pb 2+ and passivate under‐coordinated Pb 2+ defects. Consequently, the perovskite crystallization rate is reduced and high‐quality films are produced with fewer defects. The amino groups not only bind with iodide to suppress ion migration but also increase the electron density on the carbonyl groups to further enhance their passivation effect. Furthermore, the fluorine groups in DFPDA form both an effective barrier on the perovskite to improve its moisture stability and a bridge between the perovskite and HTL for effective charge transport. In addition, they show an effective doping effect in the HTL to improve its carrier mobility. With the help of the combined effects of these groups in DFPDA, the PSCs with DFPDA additive achieve a champion efficiency of 22.21% and a substantially improved stability against moisture, heat, and light.
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