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Electric Dipole Descriptor for Machine Learning Prediction of Catalyst Surface–Molecular Adsorbate Interactions

Xijun Wang, Sheng Ye, Wei Hu, Edward Sharman, Ran Liu, Yan Liu, Yi Luo, Jun Jiang

2020Journal of the American Chemical Society121 citationsDOI

Abstract

The challenge of evaluating catalyst surface-molecular adsorbate interactions holds the key for rational design of catalysts. Finding an experimentally measurable and theoretically computable descriptor for evaluating surface-adsorbate interactions is a significant step toward achieving this goal. Here we show that the electric dipole moment can serve as a convenient yet accurate descriptor for establishing structure-property relationships for molecular adsorbates on metal catalyst surfaces. By training a machine learning neural network with a large data set of first-principles calculations, we achieve quick and accurate predictions of molecular adsorption energy and transferred charge. The training model using NO/CO@Au(111) can be extended to study additional substrates such as Au(001) or Ag(111), thus exhibiting extraordinary transferability. These findings validate the effectiveness of the electric dipole descriptor, providing an efficient modality for future catalyst design.

Topics & Concepts

ChemistryDipoleMolecular descriptorCatalysisTransferabilitySurface (topology)AdsorptionArtificial neural networkMoment (physics)Chemical physicsElectric dipole momentComputational chemistryArtificial intelligenceMachine learningQuantitative structure–activity relationshipPhysical chemistryComputer scienceQuantum mechanicsOrganic chemistryPhysicsStereochemistryGeometryLogitMathematicsMachine Learning in Materials ScienceElectrocatalysts for Energy ConversionCatalytic Processes in Materials Science
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