Deep surface passivation for efficient and hydrophobic perovskite solar cells

Defect passivation has developed as an attractive approach to promote the performance of perovskite solar cells. However, robust control of the interplay between the defects and adsorbates is challenging and critical for applications. Here, hydrophobic 3-(trifluoromethyl) phenethylamine hydroiodide (CF(3)PEAI) is introduced on the surface of perovskite films. By controlling the post-treatment of the passivation layers, the amphipathic passivation agent CF(3)PEAI can form 2D perovskite and go deeply into the films (>30 nm), which can further passivate the internal defects and improve the long-term stability of perovskite films. Furthermore, the CF(3)PEAI 2D passivated perovskite films exhibit better energy level alignment, lower surface roughness, longer carrier lifetimes, lower trap state density, and higher stability than the control and the ones without annealing. Our first-principles simulation reveals that CF(3)PEAI effectively renormalizes the defective states of the vacancies with benign characteristics. The defect-adsorbate complex facilitates the manipulation of versatile electronic states for a prolonged lifetime of photoexcited carriers with improved structural integrity. Perovskite solar cells' performance is enhanced from 18.87% to 21.05% along with improved stability, which can retain 98% of initial performance after 528 h in ambient air with a humidity of 70-80%.

Automated summary

The introduction of hydrophobic 3-(trifluoromethyl) phenethylamine hydroiodide (CF(3)PEAI) passivation agent on perovskite films enhances the performance and stability of perovskite solar cells. CF(3)PEAI forms a 2D perovskite structure, penetrates deep into the films, passivates internal defects, and improves long-term stability. This passivated perovskite film exhibits better energy level alignment, longer carrier lifetimes, and higher stability, leading to an increase in solar cell performance and retention of initial performance under ambient air conditions.