“…A hybrid metal halide perovskite offers favorable optoelectronic properties, including a high absorption coefficient, long carrier lifetimes, color tunability, band gap modulation, and long diffusing lengths, among others. , This has led to its increasing applications in solar cell devices, with certified power conversion efficiency reaching 25.8%. , Moreover, most of the reported perovskite solar cells (PSCs) have been developed using low-temperature solution-processing techniques, and its fabrication has also been demonstrated for a large area. − However, stability of PSCs remains a challenge for commercialization and needs to be addressed. , It has been demonstrated that a solution-processable perovskite film contains various defects, which lead to recombination of the charge carrier and, consequently, add to instability of the device. , Various approaches, such as hot casting, anti-solvent dripping, vacuum flash treatment, solvent annealing, dimensional engineering, etc., are being attempted to reduce the defects in the perovskite layer for increasing the stability of the solar cells. − Moreover, the introduction of multifunctional organic molecules for the passivation of ionic defects in the perovskite is one of the best known techniques to increase the device performance in terms of power conversion efficiency (PCE) and stability of laboratory-scale and large-area PSCs. ,,− The multifunctional additives help to reduce the ion migration and increase the crystallinity of the perovskite. − …”