Litcius/Paper detail

Preserving surface strain in nanocatalysts via morphology control

Chuqiao Shi, Zhihua Cheng, Alberto Leonardi, Yao Yang, Michael Engel, Matthew R. Jones, Yimo Han

2024Science Advances18 citationsDOIOpen Access PDF

Abstract

Engineering strain critically affects the properties of materials and has extensive applications in semiconductors and quantum systems. However, the deployment of strain-engineered nanocatalysts faces challenges, in particular in maintaining highly strained nanocrystals under reaction conditions. Here, we introduce a morphology-dependent effect that stabilizes surface strain even under harsh reaction conditions. Using four-dimensional scanning transmission electron microscopy (4D-STEM), we found that cube-shaped core-shell Au@Pd nanoparticles with sharp-edged morphologies sustain coherent heteroepitaxial interfaces with larger critical thicknesses than morphologies with rounded edges. This configuration inhibits dislocation nucleation due to reduced shear stress at corners, as indicated by molecular dynamics simulations. A Suzuki-type cross-coupling reaction shows that our approach achieves a fourfold increase in activity over conventional nanocatalysts, owing to the enhanced stability of surface strain. These findings contribute to advancing the development of advanced nanocatalysts and indicate broader applications for strain engineering in various fields.

Topics & Concepts

Nanomaterial-based catalystNucleationMaterials scienceNanotechnologyStrain engineeringStrain (injury)Scanning transmission electron microscopyMorphology (biology)Scanning electron microscopeNanoparticleTransmission electron microscopyChemical physicsComposite materialChemistryOptoelectronicsSiliconMedicineBiologyOrganic chemistryInternal medicineGeneticsCopper-based nanomaterials and applicationsElectrocatalysts for Energy ConversionQuantum Dots Synthesis And Properties