Abstract
Electrocatalytic denitrification (ECDN) offers a sustainable prospect by enabling efficient NO(3) (-) conversion to harmless N(2). However, the N(2)-selective ECDN remains challenging due to the sluggish kinetics of N-N coupling during NO(3) (-) reduction. Here, we developed a novel electrocatalyst of dual single-atomic sites on double-shelled mesoporous carbon spheres (FeNC@MgNC-DMCS) using a continuous sequential modular assembly and pyrolysis approach. The outer Mg-N(4) shell creates medium basicity sites that function as the proton fence, which optimizes the spatial distribution of H∗ species and suppresses ∗N protonation pathways that would otherwise lead to ammonia formation. Concurrently, the inner Fe-N(4) shell promotes N-N coupling for N(2) production. 92.8% NO(3) (-) removal and 95.2% N(2) selectivity was achieved by the optimized FeNC@MgNC-DMCS catalyst. Furthermore, long-term flow cell testing demonstrated remarkable durability, highlighting the practical potential of FeNC@MgNC-DMCS for sustainable wastewater treatment applications. This work introduces a catalyst design paradigm that integrates a proton-repelling interface to decouple H∗ availability from N(2) formation pathways, thereby enabling the development of high-performance ECDN catalysts with balanced activity and selectivity for environmental remediation applications.