Polymeric carbon nitride edged with spatially isolated Donor and Acceptor for Sunlight‐driven H2O2 Synthesis and In‐situ Utilization

On‐site H2O2 activation attracts much attention in energy conversion and environment remediation et al, yet remains challenging in its highly efficient and sustainable synthesis. Herein, we grafted a pair of spatially isolated donor (methoxyphenyl unit) and acceptor (anthraquinone unit) in polymeric carbon nitride edges, which induce directional electron‐hole transfer to the two spatially separated dual active centers. Specifically, photogenerated electrons in the anthraquinone unit facilitate the 2e‐ ORR, while the methoxyphenyl unit, which gathers photogenerated holes, enables rapid 4e‐ WOR. More impressively, the anthraquinone unit also exhibits strong proton extraction capabilities to boost the generation of *OOH intermediates and H2O2. Consequently, the reported donor‐plyometric carbon nitrite‐acceptor (DPA) polymer shows a remarkable H2O2 yield of 6497.1 μM h‐1 g‐1 in pure water, surpassing traditional DP and PA catalysts. Because of its high efficiency, the H2O2 product can efficiently degrade and mineralize various organic contaminants in a continuous‐flow self‐Fenton reactor under sunlight irradiation. Our work presents an unprecedented approach to designing photocatalysts with efficient H2O2 synthesis and practical application from a molecular engineering perspective.