Out‐of‐Plane Single‐Copper‐Site Catalysts for Room‐Temperature Benzene Oxidation.

Crafting single‐atom catalysts (SACs) that possess "just right" modulated electronic and geometric structures, granting accessible active sites for direct room‐temperature benzene oxidation is a coveted objective. However, achieving this goal remains a formidable challenge. Here, we introduce an innovative in situ phosphorus‐immitting strategy using a new phosphorus source (phosphorus nitride, P3N5) to construct the phosphorus‐rich copper (Cu) SACs, designated as Cu/NPC. These catalysts feature locally protruding metal sites on a nitrogen (N)‐phosphorus (P)‐carbon (C) support (NPC). Rigorous analyses, including X‐ray absorption spectroscopy (XAS) and X‐ray photoelectron spectroscopy (XPS), validate the coordinated bonding of nitrogen and phosphorus with atomically dispersed Cu sites on NPC. Crucially, systematic first‐principles calculations, coupled with the climbing image nudged‐elastic‐band (CI‐NEB) method, provide a comprehensive understanding of the structure‐property‐activity relationship of the distorted Cu−N2P2 centers in Cu/NPC for selective oxidation of benzene to phenol production. Interestingly, Cu/NPC has shown more energetically favorable C−H bond activation compared to the benchmark Cu/NC SACs in the direct oxidation of benzene, resulting in outstanding benzene conversion (50.3 %) and phenol selectivity (99.3 %) at room temperature. Furthermore, Cu/NPC achieves a remarkable turnover frequency of 263 h−1 and mass‐specific activity of 35.2 mmol g−1 h−1, surpassing the state‐of‐the‐art benzene‐to‐phenol conversion catalysts to date. [ABSTRACT FROM AUTHOR]