Achieving a High-quality Acitive Film Through Surface Passivation to Enhance Stability of Inverted Perovskite Solar Cells
Abstract
Non-radiative recombination induced by the defects on the surfaces of perovskite films significantly impedes the enhancement of performance in perovskite solar cells (PSCs). Therefore, modifying the surface of perovskite films is crucial to achieving high-efficiency PSCs. In this study, we propose surface passivation method for perovskite films using cyanome thyltri phenylphosphonium chloride (CTPC) molecules. Our observations reveal that the C≡N group in CTPC molecule can bond with Pb2+ to passivate the undercoordinated lead sites on the perovskite layer. Additionally, the positively charged P+ moiety of CTPC molecule can interact electrostatically with I- ions, further reducing defect density. Consequently, a remarkable power conversion efficiency (PCE) of 24.63% was obtained. And the encapsulated device retained 88% of their initial PCE over a period of 1200 hours. This scholarly endeavor elucidates a novel methodology for mitigating interfacial defects and thereby propelling advancements in high-performance planar PSCs.