High‐Efficiency Silicon Solar Cells with Chemical and Field‐Effect Passivation Using Novel 2PACz/MoOx Hole‐Selective Contacts

Abstract Dopant‐free crystalline silicon (c‐Si) solar cells face critical challenges in hole transport layer (HTL) design, where conventional molybdenum oxide (MoO x ) contacts suffer from interface oxidation and insufficient electron blocking. While self‐assembled monolayers (SAMs) demonstrate potential in organic photovoltaics, their application in silicon‐based HTLs remains unexplored. In this study, a novel organic SAM (2PACz) is proposed, where phosphonic acid (PA) groups form strong coordination bonds with MoO x as HTL, aiming to improve cell performance via both chemical and field‐effect passivation. The incorporation of 2PACz raises the work function of MoO x by 0.66 eV and significantly improves the minority carrier lifetime, which, in turn increases the built‐in potential ( V bi ) to 1.06 V. These improvements contribute to a boost in both open‐circuit voltage ( V oc ) and short‐circuit current ( J sc ). Finally, the solar cell with 2PACz/MoO x ‐Au NPs‐MoO x (MAM) stack achieves a V oc of 753.3 mV, a J sc of 40.10 mA cm − 2 , a fill factor ( FF ) of 79.12%, and a conversion efficiency ( E ff ) of 23.90%. The application of 2PACz in the HTL significantly enhances solar cell performance, offering a novel strategy for interface optimization in c‐Si solar cells and other optoelectronic devices.