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Oxygen Reduction Activities of Strained Platinum Core–Shell Electrocatalysts Predicted by Machine Learning

Marlon Rück, Batyr Garlyyev, Felix Mayr, Aliaksandr S. Bandarenka, Alessio Gagliardi

2020The Journal of Physical Chemistry Letters44 citationsDOI

Abstract

Core-shell nanocatalyst activities are chiefly controlled by bimetallic material composition, shell thickness, and nanoparticle size. We present a machine learning framework predicting strain with site-specific precision to rationalize how strain on Pt core-shell nanocatalysts can enhance oxygen reduction activities. Large compressive strain on Pt@Cu and Pt@Ni induces optimal mass activities at 1.9 nm nanoparticle size. It is predicted that bimetallic Pt@Au and Pt@Ag have the best mass activities at 2.8 nm, where active sites are exposed to weak compressive strain. We demonstrate that optimal strain depends on the nanoparticle size; for instance, strengthening compressive strain on 1.92 nm sized Pt@Cu and Pt@Ni, or weakening compressive strain on 2.83 nm sized Pt@Ag and Pt@Au, can lead to further enhanced mass activities.

Topics & Concepts

Oxygen reductionPlatinumCore (optical fiber)OxygenShell (structure)Reduction (mathematics)Oxygen reduction reactionMaterials scienceChemical engineeringComputer scienceChemistryNanotechnologyCatalysisComposite materialEngineeringElectrochemistryElectrodePhysical chemistryMathematicsBiochemistryGeometryOrganic chemistryElectrocatalysts for Energy ConversionFuel Cells and Related MaterialsMachine Learning in Materials Science
Oxygen Reduction Activities of Strained Platinum Core–Shell Electrocatalysts Predicted by Machine Learning | Litcius