General machine learning models for materials prediction

ORAL

Abstract

Machine learning tools applied to problems in materials science are transforming the way we predict properties of materials. These tools enable us to compute properties of materials with the accuracy of quantum mechanics at a fraction of the time. We present five general machine learning based models which were used to simultaneously predict formation energies of 10 different materials (AgCu, AlFe, AlMg, AlNi, AlTi, CoNi, CuFe, CuNi, FeV, NbNi). We show that the results of using machine learning for materials prediction are independent of the particular model used. Prediction errors of all five models were found to qualitatively agree, with errors of the order of 1, meV/atom.

*CN, BB, CR, and GH acknowledge funding from ONR (MURI N00014-13-1-0635). MR acknowledges funding from the EU Horizon 2020 program Grant 676580, The Novel Materials Discovery (NOMAD) Laboratory, a European Center of Excellence. AS was supported by the Russian Science Foundation (Grant No 18-13-00479)

Presenters

  • Chandramouli Nyshadham

    • Brigham Young Univ - Provo
    • Brigham Young University

Authors

  • Chandramouli Nyshadham

    • Brigham Young Univ - Provo
    • Brigham Young University

  • Matthias Rupp

    • Fritz Haber Institute of the Max Planck Society

  • Brayden Bekker

    • Brigham Young University

  • Alexander Shapeev

    • Skolkovo Institute of Science and Technology

  • Tim Mueller

    • Johns Hopkins University

  • Conrad W Rosenbrock

    • Brigham Young Univ - Provo
    • Brigham Young University

  • Gabor Csanyi

    • University of Cambridge

  • David Wingate

    • Brigham Young University

  • Gus L.W. Hart

    • Brigham Young Univ - Provo
    • Brigham Young University
    • Brigham Young University - Provo