ABSTRACT Self‐assembled monolayers (SAMs) are extensively employed as hole‐selective interlayers in inverted perovskite solar cells (PSCs), yet their incomplete coverage and poor molecular ordering often induce interfacial defects and exacerbate non‐radiative recombination. To overcome these limitations, we developed a bulky methylthio‐functionalized carbazole‐based SAM, (2‐(3,6‐bis(bis(4‐(methylthio)phenyl)amino)‐9 H ‐carbazol‐9‐yl)ethyl)phosphonic acid (S‐2PACz), and implemented a sequential co‐assembly strategy utilizing cysteine (Cys). In this tailored architecture, Cys is pre‐anchored via carboxyl groups, followed by the competitive adsorption of S‐2PACz via phosphonic acid anchoring, yielding a mixed Cys‐S‐2PACz monolayer. The size complementarity and cooperative anchoring facilitated denser molecular packing and improved ordering, while synergistic methylthio and thiol functionalities jointly passivated interfacial defects. Consequently, this strategy enhanced perovskite crystallization, optimized energy‐level alignment, and facilitated efficient hole extraction. Ultimately, PSCs incorporating Cys‐S‐2PACz achieved higher power conversion efficiency, reduced recombination losses, and demonstrated superior thermal, operational, and outdoor stability compared with devices based on single‐component SAMs. This work establishes competitive co‐assembly as an effective interfacial engineering strategy, providing a scalable route to tailored SAM architectures for high‐performance and durable p–i–n PSCs.
Xia et al. (Sun,) studied this question.