超分子化学
钙钛矿(结构)
纳米技术
光伏
材料科学
晶体工程
化学
超分子组装
超分子聚合物
能量转换效率
商业化
材料设计
固态化学
工具箱
材料化学
分子
作者
Zhenyang Chen,Fangnan Shen,Xiuji Yi,Guangyi Cao,Xinyi Lin,Fancong Zeng,Gengling Liu,Yijia Chen,Meifang Yang,Tian Tian,Wen-Guang Li,Huan Pang
摘要
Although the power conversion efficiency has been greatly improved, the commercialization of perovskite solar cells is hindered by inherent instability and the environmental risk of lead leakage. This review describes how supramolecular chemistry gives us a versatile molecular toolbox for tackling these problems. Engineered macrocyclic molecules such as cyclodextrins, porphyrins, and crown ethers that can be used to control the interface passivation, crystallization, carrier transport, and stability by means of programmable noncovalent interactions. It improves both the device performance and operational stability in harsh environments such as heat, light, and moisture. Supramolecular chemistry can effectively decrease the quantity of lead that leaks out, resolving this significant environmental issue. The fundamental mechanisms of supramolecular chemistry are analyzed, and the future direction of guiding the development of efficient, stable, and sustainable perovskite photovoltaics is predicted.
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