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Enhancing catalytic performance of dilute metal alloy nanomaterials

Mathilde Luneau, Erjia Guan, Wei Chen, Alexandre C. Foucher, Nicholas Marcella, Tanya Shirman, David M. A. Verbart, Joanna Aizenberg, Michael Aizenberg, Eric A. Stach, R. J. Madix, Anatoly I. Frenkel, C. M. Friend

2020Communications Chemistry77 citationsDOIOpen Access PDF

Abstract

Abstract Dilute alloys are promising materials for sustainable chemical production; however, their composition and structure affect their performance. Herein, a comprehensive study of the effects of pretreatment conditions on the materials properties of Pd 0.04 Au 0.96 nanoparticles partially embedded in porous silica is related to the activity for catalytic hydrogenation of 1-hexyne to 1-hexene. A combination of in situ characterization and theoretical calculations provide evidence that changes in palladium surface content are induced by treatment in oxygen, hydrogen and carbon monoxide at various temperatures. In turn, there are changes in hydrogenation activity because surface palladium is necessary for H 2 dissociation. These Pd 0.04 Au 0.96 nanoparticles in the porous silica remain structurally intact under many cycles of activation and deactivation and are remarkably resistant to sintering, demonstrating that dilute alloy catalysts are highly dynamic systems that can be tuned and maintained in a active state.

Topics & Concepts

CatalysisSinteringNanomaterialsMaterials scienceAlloyCarbon monoxideDissociation (chemistry)PalladiumChemical engineeringPorosityHydrogenNanoparticleMetalHydrogen productionChemistryNanotechnologyMetallurgyOrganic chemistryComposite materialEngineeringCatalytic Processes in Materials ScienceNanomaterials for catalytic reactionsElectrocatalysts for Energy Conversion
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