Functional agents have been verified to efficiently enhance device performance of perovskite solar cells (PSCs) through surface engineering. However, the influence of intrinsic characteristics of molecules on final device performance has been overlooked. Here, we develop a surface reconstruction strategy to enhance the efficiency of inverted PSCs by mitigating the adverse effects of lead chelation (LC) molecules. We choose bathocuproine (BCP), as the representative of LC molecules for its easy accessibility and outstanding optoelectronic properties. During this strategy, BCP molecules on perovskite surface are first dissolved in solvents and then captured specially by undercoordinated Pb2+ ions, preventing adverse n-type doping by the molecules themselves. In this case, the BCP molecule exhibits outstanding passivation effect on perovskite surface, which leads to an obviously increased open-circuit voltage (VOC). Therefore, a record PCE of 25.64% for NiOx-based inverted PSCs is achieved, maintaining over 80% of initial efficiency after exposure to ambient condition for ∼1500 hours. This article is protected by copyright. All rights reserved.
Keywords: chelation; defects; inverted; perovskite solar cell; surface reconstruction.
This article is protected by copyright. All rights reserved.