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Space-Confined Surface Layer in Superstructured Ni–N–C Catalyst for Enhanced Catalytic Degradation of <i>m</i>-Cresol by PMS Activation

Chengyu Jin, Peiwei Han, Gao Li, Yanan Zhang, Hao Sun, Wenjie Shen, Chenglin Sun, Huangzhao Wei

2022ACS Applied Materials & Interfaces25 citationsDOI

Abstract

The broad application of peroxymonosulfate (PMS)-assisted oxidation by heterogeneous catalysts for contaminant removal suffers from the limitation of low PMS decomposition efficiency and consequent excessive electrolyte residues. In this work, we report that a micrometer-scale superstructured Ni–N–C catalyst Ni-NCNT/CB with a nanotube-array surface layer exhibits ultrahigh m-cresol removal efficiency with low PMS input and possesses ∼17-fold higher catalytic specific activity (reaction rate constant normalized to per Ni–Nx site) compared to the traditional Ni-SAC catalyst. Electron paramagnetic resonance results indicate that 1O2 is the dominant oxygen species, and Ni-NCNT/CB with a space-confined layer exhibits high 1O2 utilization for m-cresol degradation. Electrochemical impedance spectroscopy and a normalized k value of Ni-NCNT/CB confirm the spatial confinement effect on the catalyst surface, which is beneficial for regulating the mass transfer and exerting the high activity of active sites. This study gives a new application for spatial confinement, and the configuration of Ni-NCNT/CB may guide a rational catalyst design for AOP wastewater treatment.

Topics & Concepts

CatalysisMaterials scienceChemical engineeringDegradation (telecommunications)Dielectric spectroscopyElectrolyteElectrochemistryNuclear chemistryChemistryElectrodePhysical chemistryOrganic chemistryTelecommunicationsComputer scienceEngineeringAdvanced oxidation water treatmentAdvanced Photocatalysis TechniquesElectrocatalysts for Energy Conversion
Space-Confined Surface Layer in Superstructured Ni–N–C Catalyst for Enhanced Catalytic Degradation of <i>m</i>-Cresol by PMS Activation | Litcius