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Interpretable Machine Learning Models for Practical Antimonate Electrocatalyst Performance.

Shyam Deo1,2, Melissa E Kreider1,2, Gaurav Kamat1,2

  • 1Department of Chemical Engineering, Stanford University, Stanford, CA 94305, United States.

Chemphyschem : a European Journal of Chemical Physics and Physical Chemistry
|March 28, 2024
PubMed
Summary
This summary is machine-generated.

Simple machine learning models accurately predict catalyst performance for the oxygen reduction reaction. Key experimental and structural factors were identified, guiding catalyst design for improved efficiency.

Keywords:
electrocatalysismachine learningmaterials design

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Area of Science:

  • Catalysis
  • Materials Science
  • Computational Chemistry

Background:

  • Predicting catalyst performance under reaction conditions is complex due to in situ surface evolution and solid-liquid interfaces.
  • Machine learning offers a potential solution for predicting catalytic behavior, even with limited data.

Purpose of the Study:

  • To develop machine learning models for predicting experimentally observed onset potentials.
  • To identify key descriptors governing catalytic performance in transition-metal antimony oxides for the oxygen reduction reaction.

Main Methods:

  • Utilized density functional theory (DFT) to obtain bulk atomic and electronic structural descriptors.
  • Employed human-interpretable genetic programming models incorporating experimental conditions and DFT descriptors.
  • Focused on non-precious transition-metal antimony oxide nanoparticulate catalysts for the oxygen reduction reaction.

Main Results:

  • Successfully predicted experimentally observed onset potentials using simple machine learning models.
  • Identified crucial experimental factors and supplemental bulk electronic/atomic descriptors influencing onset potentials.
  • Validated predictions by experimentally confirming that scandium doping in nickel antimony oxide increases onset potential.

Conclusions:

  • Machine learning, even with small datasets, can effectively model catalytic performance.
  • Macroscopic experimental factors are critical descriptors for predicting catalyst behavior.
  • The identified descriptors provide guidance for tuning catalysts to enhance onset potentials.