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Introducing Stacking Faults into Three-Dimensional Branched Nickel Nanoparticles for Improved Catalytic Activity

Zeno Rizqi Ramadhan, Agus R. Poerwoprajitno, Soshan Cheong, Richard F. Webster, Priyank V. Kumar, Steffen Cychy, Lucy Gloag, Tânia M. Benedetti, Christopher E. Marjo, Martin Muhler, Dawei Wang, J. Justin Gooding, Wolfgang Schuhmann, Richard D. Tilley

2022Journal of the American Chemical Society50 citationsDOIOpen Access PDF

Abstract

Creating high surface area nanocatalysts that contain stacking faults is a promising strategy to improve catalytic activity. Stacking faults can tune the reactivity of the active sites, leading to improved catalytic performance. The formation of branched metal nanoparticles with control of the stacking fault density is synthetically challenging. In this work, we demonstrate that varying the branch width by altering the size of the seed that the branch grows off is an effective method to precisely tune the stacking fault density in branched Ni nanoparticles. A high density of stacking faults across the Ni branches was found to lower the energy barrier for Ni 2+ /Ni 3+ oxidation and result in enhanced activity for electrocatalytic oxidation of 5-hydroxylmethylfurfural. These results show the ability to synthetically control the stacking fault density in branched nanoparticles as a basis for enhanced catalytic activity.

Topics & Concepts

StackingChemistryNanomaterial-based catalystCatalysisNanoparticleStacking faultNickelMetalNanotechnologyChemical engineeringCombinatorial chemistryOrganic chemistryMaterials scienceEngineeringElectrocatalysts for Energy ConversionCatalytic Processes in Materials ScienceAdvanced battery technologies research
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