Abstract

Abstract Thermodynamically favorable electrooxidation of organics coupled with hydrogen production as an alternative to overall water splitting is rapidly developing due to low energy consumption and high value. But understanding the relationship between catalyst reconstruction and performance in depth remains a challenge. Herein, DFT calculations are used as a theoretical guide to adjust the local coordination environment and electronic structure of Ni 3 S 2 by Fe doping, which promotes the self‐reconstruction of catalyst and nitrile evolution reaction performance. The overall reaction of benzylamine electrooxidation coupled with hydrogen production achieves a 14.5‐fold improvement in hydrogen production compared to water electrolysis at the same potential, almost completely converting benzylamine to high‐value benzonitrile (99% product yield). In situ spectroscopy and X‐ray absorption fine structure spectroscopy demonstrate that the excellent electrocatalytic performance due to Fe doping induces surface self‐reconstruction of Ni 3 S 2 to NiOOH at low potential, and significantly reduces the rate‐determining step energy barriers for CN bonds to CN bonds. This work provides theoretical guidance in designing and preparing efficient catalysts for the electrosynthesis of nitrile compounds coupled with hydrogen production.