Efficient and stable perovskite solar cells based on blade-coated CH3NH3PbI3 thin films fabricated using ?green? solvents under ambient conditions

Metal halide perovskites are considered the most promising candidates for solar cells of the decade due to their exceptional optical and electronic properties. The power conversion efficiency of metal halide perovskites, when incorporated as the active layer of solar cells, has become comparable to that observed for conventional silicon solar cells. However, the stability, scaleup, green solvent usage, and fabrication in ambient conditions of metal halide perovskites need to be solved for commercial applications. Here, we report the fabrication of blade-coated methylammonium lead iodide (MAPbI3) perovskite thin films using methylamine and acetonitrile as green solvents under ambient conditions. Our perovskite films are initially prepared from low purity PbI2 (99%) and are blade-coated in dry air at relative humidity (RH) levels above 30%. A significant advantage of fabricating our perovskite thin films via blade-coating protocols is that there is a minimal amount of precursors (5 mu L) used compared to spin-coating methods (50 mu L-60 mu L) for a 4 cm2 substrate. With the addition of a small amount of an organic halide salt, namely, phenethylammonium chloride, the film crystallinity is improved and non-radiative recombination is suppressed, resulting in power conversion efficiencies over 20%. In addition, the device maintains more than 95% of its initial efficiency after 500 h under continuous light illumination of 1-sun at open circuit conditions, 50 degrees C and 60% RH. The above method leads a path towards the commercial fabrication of perovskite solar cells.

Automated summary

Metal halide perovskites show great potential as solar cell materials due to their exceptional optical and electronic properties. This study presents a method for fabricating perovskite thin films using green solvents and blade-coating techniques under ambient conditions. The resulting films exhibit high power conversion efficiencies and excellent stability, making them a promising candidate for commercial perovskite solar cells.