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Adjacent‐Confined Pyrolysis for High‐Density Phase Boundaries in Mo<sub>2</sub>C Nanosheets to Boost Oxygen Evolution

Wenhua Cong, Weikang Dong, Yuanyuan Yan, Xun Cao, Yike Xu, Zhenyu Liu, Jijian Liu, Jin Wook Yang, Xuguang Liu, Yang Yang, Longyi Fu, Meiling Wang, Tianyuan Zhang, Jiadong Zhou

2024Advanced Functional Materials26 citationsDOIOpen Access PDF

Abstract

Abstract Heterostructure or doping engineering on Mo 2 C by coupling with transition metal nanoparticles/atoms can optimize catalytic activities for oxygen evolution reaction (OER). However, the intrinsic catalytic activity of Mo 2 C is not fully stimulated at the atomic level, which is challenging. Herein, an adjacent‐confined pyrolysis strategy to manipulate the intrinsic electronic structure of Mo 2 C directly is reported. During the nucleation and growth of Mo 2 C, the replacement of Mo atoms by adjacent Ni atoms induces the generation of high‐density phase boundaries (PBs) with alternating face‐centered cubic (fcc) and hexagonal close‐packed (hcp) hetero‐phase. The lattice deformity in PBs affords an ultrahigh density of active sites, endowing Mo 2 C nanosheets with excellent OER activity and superior stability. Theoretical calculations reveal that introduced Ni atoms activate the adjacent Mo sites and optimize the thermodynamic reaction energetics for enhanced OER activity. The work offers a general adjacent‐confined pyrolysis strategy to achieve PBs‐controlling in Mo 2 C nanosheets for catalytic application and beyond.

Topics & Concepts

Materials scienceNucleationCatalysisOxygen evolutionPyrolysisChemical physicsNanoparticlePhase (matter)HeterojunctionDensity functional theoryNanotechnologyChemical engineeringCrystallographyPhysical chemistryComputational chemistryOptoelectronicsThermodynamicsEngineeringBiochemistryPhysicsChemistryElectrochemistryElectrodeOrganic chemistryMXene and MAX Phase MaterialsElectrocatalysts for Energy Conversion2D Materials and Applications