Ultralong Carrier Lifetime Exceeding 20 mu s in Lead Halide Perovskite Film Enable Efficient Solar Cells
作者:
Guo, JH (Guo, Jiahao) [1] , [2] ; Wang, BZ (Wang, Bingzhe) [3] ; Lu, D (Lu, Di) [1] , [2] ; Wang, T (Wang, Ting) [1] , [2] ; Liu, TT (Liu, Tingting) [1] , [2] ; Wang, R (Wang, Rui) [1] , [2] ; Dong, XY (Dong, Xiyue) [1] , [2] ; Zhou, T (Zhou, Tong) [1] , [2] ; Zheng, N (Zheng, Nan) [4] ; Fu, Q (Fu, Qiang) [1] , [2] ; Xie, ZQ (Xie, Zengqi) [4] ; Wan, XJ (Wan, Xiangjian) [1] , [2] , [5] ; Xing, GC (Xing, Guichuan) [3] ; Chen, YS (Chen, Yongsheng) [1] , [2] , [5] ; Liu, YS (Liu, Yongsheng) [1] , [2] , [5]
DOI
10.1002/adma.202212126
在线发表
MAY 2023
已索引
2023-06-05
文献类型
Article; Early Access
摘要
The carrier lifetime is one of the key parameters for perovskite solar cells (PSCs). However, it is still a great challenge to achieve long carrier lifetimes in perovskite films that are comparable with perovskite crystals owning to the large trap density resulting from the unavoidable defects in grain boundaries and surfaces. Here, by regulating the electronic structure with the developed 2-thiopheneformamidinium bromide (ThFABr) combined with the unique film structure of 2D perovskite layer caped 2D/3D polycrystalline perovskite film, an ultralong carrier lifetime exceeding 20 mu s and carrier diffusion lengths longer than 6.5 mu m are achieved. These excellent properties enable the ThFA-based devices to yield a champion efficiency of 24.69% with a minimum V-OC loss of 0.33 V. The unencapsulated device retains approximate to 95% of its initial efficiency after 1180 h by max power point (MPP) tracking under continuous light illumination. This work provides important implications for structured 2D/(2D/3D) perovskite films combined with unique FA-based spacers to achieve ultralong carrier lifetime for high-performance PSCs and other optoelectronic applications.