In Situ Grown RuNi Alloy on ZrNiN<sub>x</sub> as a Bifunctional Electrocatalyst Boosts Industrial Water Splitting
Yaojin Zhang, Zijian Li, Haeseong Jang, Min Gyu Kim, Jaephil Cho, Shangguo Liu, Xien Liu, Qing Qin
Abstract
Abstract Alkaline water electrolysis represents a pivotal technology for green hydrogen production yet faces critical challenges including limited current density and high energy input. Herein, a heterostructured bimetallic nitrides supported RuNi alloy (RuNi/ZrNiN x ) is developed through in situ epitaxial growth under ammonolysis, achieving exceptional bifunctional activity and durability for hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) in 1 m KOH electrolyte. The RuNi/ZrNiN x exhibits a HER current density of −2 A cm −2 at an overpotential of 392.8 mV, maintaining initial overpotential after 1000 h continuous electrolysis at −500 mA cm −2 . For OER, it delivers a current density of 2 A cm −2 at 1.822 V versus RHE, and sustains stable operation for 705 h at 500 mA cm −2 . Experimental and theoretical studies unveil that the charge redistribution‐induced high‐valence Zr centers effectively polarize H─O bonds and promote water dissociation, and the electron‐deficient interface Ru sites optimize hydrogen desorption kinetics. Dynamic OH spillovers from Zr sites to the adjacent tri‐coordinated Ni hollow sites in NiN x promote rapid *OH intermediate desorption and active site regeneration. Notably, the tri‐coordinated Ni hollow sites in NiN x proximal to Zr atoms exhibit tailored adsorption strength for oxo‐intermediates, enabling a more energetically favorable pathway for O 2 production.