Litcius/Paper detail

Caged-Cation-Induced Lattice Distortion in Bronze TiO<sub>2</sub>for Cohering Nanoparticulate Hydrogen Evolution Electrocatalysts

Gaoxin Lin, Qiangjian Ju, Lijia Liu, Xuyun Guo, Ye Zhu, Zhuang Zhang, Chendong Zhao, Yingjie Wan, Minghui Yang, Fuqiang Huang, Jiacheng Wang

2022ACS Nano46 citationsDOIOpen Access PDF

Abstract

Defect engineering provides a promising approach for optimizing the trade-off between support structures and active nanoparticles in heterojunction nanostructures, manifesting efficient synergy in advanced catalysis. Herein, a high density of distorted lattices and defects are successfully formed in bronze TiO2 through caging alkali-metal Na cations in open voids (Na-TiO2(B)), which could efficiently cohere nanoparticulate electrocatalysts toward alkaline hydrogen evolution reaction (HER). The RuMo bimetallic nanoparticles could directionally anchor on Na-TiO2(B) with a certain angle of ∼22° due to elimination of the lattice mismatch, thus promoting uniform dispersion and small sizing of supported nanoparticles. Moreover, caging Na ions could significantly enhance the hydrophilicity of the substrate in RuMo/Na-TiO2(B), leading to the strengthening synergy of water dissociation and hydrogen desorption. As expected, this Na-caged nanocomposite catalyst rich with structural perturbations manifests a 6.4-fold turnover frequency (TOF) increase compared to Pt/C. The study provides a paradigm for designing stable nano-heterojunction catalysts with lattice-distorted substrates by caging cations toward advanced electrocatalytic transformations.

Topics & Concepts

Materials scienceCatalysisBimetallic stripNanoparticleDissociation (chemistry)HeterojunctionChemical engineeringNanocompositeNanotechnologyNanocrystalWater splittingNanostructurePhotocatalysisMetalChemistryPhysical chemistryOptoelectronicsMetallurgyEngineeringBiochemistryElectrocatalysts for Energy ConversionAdvanced Memory and Neural ComputingAdvanced battery technologies research