Abstract
The quality of perovskite light-absorbing materials plays a vital role in the photovoltaic performance of perovskite solar cells. Herein, we present a facile surface engineering technique through post-treating pure MAPbI(3) films with formamidinium iodide (FM) solution, leading to mixed-cation FA(x)MA(1-x)PbI(3) perovskite with substantial grain dimensions and a compact and uniform morphology. It is noted that the film post-treated with 20 mg.mL(-1) FM solution produces a highly crystalline and stable lattice structure with the features like the decreased defect density, improved electron transport, and long carrier lifetime. The optimized device based on the FA(x)MA(1-x)PbI(3) obtained from the cation-intermixing technique shows a promising power conversion efficiency of 20.21%, which is even superior than that of the device based on the mixed-cation perovskite from the traditional method without post-treatment (19.08%). Moreover, the device based on the developed method also shows a better stability. These findings provide a simple procedure to fabricate high-quality mixed-cation perovskite layers for high-performance devices via controlling the crystallization and reducing density of defect states.