双功能
材料科学
结晶
钙钛矿(结构)
分子
钙钛矿太阳能电池
钝化
化学工程
结晶度
涂层
能量转换效率
吸附
纳米技术
润湿
太阳能电池
光伏
蒸发
成核
甲脒
三碘化物
原子转移自由基聚合
卤化物
溶剂
光伏系统
四氢呋喃
作者
Ziling Zhang,Jianfei Yang,Ziyi Wu,Xuanling Liu,Han Zhong,Xuanyu Wang,Jiazheng Su,Han Wang,J. W. Lee,Xin Li,Hong Lin
标识
DOI:10.1002/adfm.202522596
摘要
Abstract Flexible perovskite solar cells possess great application potential in both stationary and mobile photovoltaics because of their lightweight and bendable features. However, the poor crystallinity of perovskite and the fragility of the buried interface on flexible substrates with a rough surface and poor wettability result in efficiency and durability losses. Herein, the critical role of buried interface quality in governing dimethyl sulfoxide (DMSO) evaporation and the sequential crystallization kinetics is uncovered. A facile and effective strategy is implemented by adopting several bifunctional polar molecules with different groups, including 3‐aminopropanoic acid (APAC), 3‐iodo‐1‐propanol (IDPA), and 3‐iodopropionic acid (IDPAC), to modify the SnO 2 /perovskite interface. Multifunctional molecules bearing appropriate functional groups can concurrently passivate interfacial defects on both sides, which strongly adsorb DMSO molecules, enabling adequate solvent removal during crystallization and minimizing buried interfacial voids. This dual‐passivation strategy simultaneously yields stress‐relaxed flexible perovskite films while strengthening interfacial adhesion and charge transport properties. Consequently, IDPAC‐modified rigid cells achieve a champion efficiency up to 25.59% (certified 24.92%), while flexible devices exhibit a seductive efficiency of 24.90% (certified 24.39%) and retain 92% of the initial efficiency after bending 10 000 cycles with a radius of 5 mm.
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