Two-Stage Ultraviolet Degradation of Perovskite Solar Cells Induced by the Oxygen Vacancy-Ti(4+) States

The failure of perovskite solar cells (PSCs) under ultraviolet (UV) irradiation is a serious barrier of commercial utilization. Here, a two-stage degradation process of TiO(2)-based PSCs is discovered under continuous UV irradiation in an inert atmosphere. In the first decay stage, oxygen vacancy-Ti(3+) (Ti(3+)-V(O)) transform into active Ti(4+)-V(O) trap states under UV excitation and cause photocarrier loss. Furthermore, Ti(4+)-V(O) states can convert back into Ti(3+)-V(O) states through oxidizing I(−), which result in the accumulation of I(3)(−). Sequentially, the rapid decomposition of perovskite accelerated by increasing I(3)(−) replaces the photocarrier loss as the dominant mechanism leading to the second decay stage. Then, a universal method is proposed to improve the UV stability by blocking the transformation of Ti(3+)-V(O) states, which can be realized by polyethyleneimine ethoxylated (PEIE) modified layer. The optimized devices remain ∼75% of its initial efficiency (20.51%) under UV irradiation at 72 days, whereas the normal devices fail completely.