Selective Two‐Electron Phenol Oxidation Polymerization for Water Purification

ABSTRACT

Highly reactive phenoxonium ion (PhO ⁺ ), generated via two‐electron oxidation, exhibits remarkable efficacy in polymerizing and removing phenolic contaminants. However, the sequential two‐electron abstraction from phenol to form PhO ⁺ remains a significant kinetic and thermodynamic challenge. Herein, we report an N‐bridged double‐iron site (≡Fe─N─Fe ≡) catalyst that enables PhO ⁺ generation through peroxymonosulfate (PMS) activation. In situ spectroscopy and theoretical calculations reveal that PMS adsorbs onto the ≡Fe─N─Fe ≡ site via both peroxide oxygen atoms (─O─O─), forming a ≡Fe‐(μO─O)─Fe≡ intermediate. This unique structure provides dual low‐lying Fe─O σ*(‐ p _z ) orbitals, and minimizes the energy gap between the Fe orbital and the O─O σ* orbital, thereby catalyzing two‐step single‐electron transfer from phenol to the ─O─O─ and enabling the PhO ⁺ formation. This PhO ⁺ ‐induced C─O coupling polymerization achieves an 81.8% polymerization transfer ratio, significantly higher than that obtained via the phenoxy radical (PhO•)‐mediated process (35.0%). This system enables the rapid phenol removal (98.1% in 3 min) and the effective treatment of coking wastewater, maintaining > 97% phenol removal over 10 d in a continuous‐flow reactor. Our work provides an atomic‐level design principle for steering oxidation pathways, opening a sustainable route for water purification that simultaneously eliminates pollutants and recovers carbon resources.