LAUSR

Abstract Denitrification of nitrate (NO3−) to dinitrogen (N2) is of fundamental importance in water pollution control and environmental remediation. Conventional catalytic denitrification requires the use of expensive and often toxic metal such as Pd and Cu. Nitrate also can be rapidly reduced by environment-friendly nanoscale Zero-Valent Iron (nZVI), unfortunately the end product is mostly ammonia. Herein, nZVI is reconstructed with nitrogen-doping, dispersed and encapsulated within a tubular nitride carbon (nZVI@NC) as an electrocatalyst, regulating the multi-electron transfer reaction. The tubular iron structure is about 400–450 nm in length, has a diameter around 70–100 nm and wall thicknesses about 20–25 nm, surface area at 1445 m2/g. The nZVI@NC exhibits high nitrate removal efficiency (92%) and N2 selectivity (97%), and maintains consistent performance in the pH range of 5–11. With nitrate selectively adsorbing on the highly porous and hydrophilic NC layer, the N-O bond is efficiently cleaved by gaining electrons from nZVI and activated hydrogen [H] to produce benign N2. Meanwhile, the intermediate product NH4+ can be oxidized to N2 by the HClO generated on the anode. This study points to promising prospects of modified nZVI for applications in denitrification and environmental remediation.