Litcius/Paper detail

Interfacial Electronic Interactions in Ni <sub>1</sub> Cu Single-Atom Alloys Enhance Carbon Dioxide Electrocatalytic Conversion

Hongwei Pan, Wenwen Cai, Chengdong Yang, Xiya Guan, Yueqing Wang, Xueying Cao, Jizhen Ma, Jintao Zhang

2025Nano Letters7 citationsDOI

Abstract

Copper-based single-atom alloys (SAAs) exhibit unique capabilities to catalyze the conversion of CO 2 into valuable fuels and chemicals, yet their high polarization often induces surface reconstruction, limiting their stability under practical conditions. Here, a novel SAA catalyst, Ni 1 Cu/NC, featuring atomically dispersed Ni on ∼3 nm Cu nanoparticles anchored on a nitrogen-doped carbon substrate was developed. Density functional theory suggests that energy-aligned and symmetry-compatible mixing of Ni 3d with Cu 4s/4p states enhances s/p–d hybridization on the Cu sites and induces partial delocalization of Cu d-band electrons, modulating the adsorption of key intermediates. As a result, Ni 1 Cu/NC achieved near-unity CO Faradaic efficiency (FE CO ) and remarkable durability of 160 h. Furthermore, coupling the catalyst with an anode for the 5-hydroxymethylfurfural oxidation reaction in a solar-driven system renders a high 2,5-furandicarboxylic acid yield of 97.3%. This work provides a comprehensive framework for the rational design of supported SSA catalysts.

Topics & Concepts

Faraday efficiencyMaterials scienceAdsorptionCatalysisDensity functional theoryChemical engineeringAnodePolarization (electrochemistry)NanoparticleRedoxInorganic chemistrySubstrate (aquarium)Carbon dioxideRational designTransition metalNanoscopic scaleElectrochemistryYield (engineering)NanotechnologyElectrochemical reduction of carbon dioxideElectrocatalystCarbon fibersElectrodeDelocalized electronCarbon nanotubeBimetallic stripCurrent densityElectronic effectLimitingSynergistic catalysisCoupling (piping)Coupling reactionWork (physics)CO2 Reduction Techniques and CatalystsCatalysts for Methane ReformingCatalysis for Biomass Conversion