The power conversion efficiency (PCE) of perovskite solar cells (PSCs) has approached that of silicon-based counterparts, yet their limited long-term stability remains a critical obstacle to commercialization. In this study, laser scribing is identified as a crucial factor affecting the stability of perovskite solar modules (PSMs), as evidenced by the differing degradation rates observed between PSMs and PSCs. Detailed characterization reveals that the P1 scribe areas exhibit poor crystalline quality and accelerated degradation, primarily due to mismatched crystallization kinetics. Furthermore, the P2 and P3 scribing processes induce localized thermal damage, resulting in material decomposition that further undermines module stability. Therefore, we propose a strategy for regulation of perovskite crystallization kinetics by (E)-But-2-ene-1,4-diamine dihydrochloride, which promotes high-quality, preferentially oriented perovskite films to enhance their environmental tolerance. As a result, PSMs with aperture areas of 25 cm² and 100 cm² achieve impressive efficiencies of 24.70% and 23.89%, respectively. Notably, the 100 cm² PSM attains a certified record efficiency of 23.55%. Furthermore, unencapsulated PSMs retain 93% of their initial PCE after 3,120 hours of storage in ambient air (~15% RH), following the ISOS-D-1 standard. This work provides a module-level perspective for advancing the understanding and improvement of long-term stability in perovskite photovoltaics. Perovskite solar cells rival silicon in efficiency but suffer from poor long-term stability, partly due to laser scribing defects. The authors regulate crystallization using (E)-But-2- ene-1,4-diamine dihydrochloride, achieving high module efficiency and enhanced durability.
Xie et al. (Fri,) studied this question.