Abstract
Triple-cation perovskite solar cells (PSCs) exhibit better long-term stability as compared to FAPbI3 devices but also have more defects such as undercoordinated lead ions (Pb2+), halide vacancies, and organic cation vacancies in film. Herein, ammonium formate (NH4HCO2) is introduced and forms a stable NH4HCO2-PbI2 adduct onto the surface of perovskite (FA0.945MA0.025Cs0.03Pb(I0.975Br0.025)3) to patch grain boundary cracks and passivate interfacial defects. The density functional theory calculation results indicate that there is a strong interface interaction between perovskite surface and NH4HCO2, and the defects are well anchored by forming Pb··COOH bond and I··NH4 bond. The density of states (DOS) proves that surface trap states (around the Fermi level) created by the I vacancy is effectively eliminated, which is consistent with the experimental results of suppressing non-radiative recombination at the interface. As expected, the optimized PSCs achieve a champion power conversion efficiency (PCE) of 24.62%, which is much higher than the value of control devices with a PCE of 23.45%. Moreover, the unencapsulated devices exhibit remarkable long-term stability in air with 40% RH at 25°C. This work provides a simple defect multiple passivation strategy to build PSCs with high efficiency and stability.