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Lowering the Exponential Wall: Accelerating High-Entropy Alloy Catalysts Screening using Local Surface Energy Descriptors from Neural Network Potentials (2404.08413v3)

Published 12 Apr 2024 in quant-ph and cond-mat.mtrl-sci

Abstract: Computational screening is indispensable for the efficient design of high-entropy alloys (HEAs), which hold considerable potential for catalytic applications. However, the chemical space of HEAs is exponentially vast with respect to the number of constituent elements, making even machine learning-based screening calculations time-intensive. To address this challenge, we propose a rapid method for predicting HEA properties using data from monometallic systems (or few-component alloys). Central to our approach is the newly introduced local surface energy (LSE) descriptor, which captures local surface reactivity at atomic resolution. We established a correlation between LSE and adsorption energies using monometallic systems. Using this correlation in a linear regression model, we successfully estimated molecular adsorption energies on HEAs with significantly higher accuracy than a conventional descriptor (i.e., generalized coordination numbers). Furthermore, we developed high-precision models by employing both classical and quantum machine learning. Our method enabled CO adsorption-energy calculations for 1000 quinary nanoparticles, comprising 201 atoms each, within a few days, considerably faster than density functional theory, which would require hundreds of years or neural network potentials, which would have taken hundreds of days. The proposed approach accelerates the exploration of the vast HEA chemical space, facilitating the design of novel catalysts.

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References (31)
  1. E. J. Pickering and N. G. Jones, High-entropy alloys: a critical assessment of their founding principles and future prospects, International Materials Reviews 61, 183 (2016).
  2. E. P. George, D. Raabe, and R. O. Ritchie, High-entropy alloys, Nature Reviews Materials 4, 515 (2019).
  3. K. Kusada, D. Wu, and H. Kitagawa, New aspects of platinum group metal-based solid-solution alloy nanoparticles: Binary to high-entropy alloys, Chemistry – A European Journal 26, 5105 (2020).
  4. N. Mardirossian and M. Head-Gordon, Thirty years of density functional theory in computational chemistry: an overview and extensive assessment of 200 density functionals, Molecular physics 115, 2315 (2017).
  5. I. Y. Zhang and A. Grüneis, Coupled cluster theory in materials science, Frontiers in Materials 6, 123 (2019).
  6. I. Shavitt and R. J. Bartlett, Many-body methods in chemistry and physics: MBPT and coupled-cluster theory (Cambridge university press, 2009).
  7. J. Behler and M. Parrinello, Generalized neural-network representation of high-dimensional potential-energy surfaces, Physical Review Letters 98, 10.1103/physrevlett.98.146401 (2007).
  8. J. Behler, Atom-centered symmetry functions for constructing high-dimensional neural network potentials, The Journal of Chemical Physics 134, 074106 (2011).
  9. J. Behler, Constructing high-dimensional neural network potentials: a tutorial review, International Journal of Quantum Chemistry 115, 1032 (2015).
  10. J. S. Smith, O. Isayev, and A. E. Roitberg, ANI-1: an extensible neural network potential with DFT accuracy at force field computational cost, Chemical Science 8, 3192 (2017).
  11. T. Xie and J. C. Grossman, Crystal graph convolutional neural networks for an accurate and interpretable prediction of material properties, Physical Review Letters 120, 10.1103/physrevlett.120.145301 (2018).
  12. C. Chen and S. P. Ong, A universal graph deep learning interatomic potential for the periodic table, Nature Computational Science 2, 718 (2022).
  13. C. M. Clausen, J. Rossmeisl, and Z. W. Ulissi, Adapting oc20-trained equiformerv2 models for high-entropy materials, arXiv preprint arXiv:2403.09811  (2024).
  14. J. Dean, M. G. Taylor, and G. Mpourmpakis, Unfolding adsorption on metal nanoparticles: Connecting stability with catalysis, Science advances 5, eaax5101 (2019).
  15. Z. Lu, Z. W. Chen, and C. V. Singh, Neural network-assisted development of high-entropy alloy catalysts: decoupling ligand and coordination effects, Matter 3, 1318 (2020).
  16. Z. Yang and W. Gao, Applications of machine learning in alloy catalysts: rational selection and future development of descriptors, Advanced Science 9, 2106043 (2022).
  17. K. Momma and F. Izumi, VESTA3 for three-dimensional visualization of crystal, volumetric and morphology data, Journal of Applied Crystallography 44, 1272 (2011).
  18. H. Nakai, Energy density analysis with kohn–sham orbitals, Chemical Physics Letters 363, 73 (2002).
  19. M. Yu, D. R. Trinkle, and R. M. Martin, Energy density in density functional theory: Application to crystalline defects and surfaces, Physical Review B 83, 10.1103/physrevb.83.115113 (2011).
  20. J. J. Eriksen, Mean-field density matrix decompositions, The Journal of Chemical Physics 153, 214109 (2020).
  21. S. R. Bahn and K. W. Jacobsen, An object-oriented scripting interface to a legacy electronic structure code, Comput. Sci. Eng. 4, 56 (2002).
  22. G. Kresse and J. Hafner, Ab initio molecular dynamics for open-shell transition metals, Physical Review B 48, 13115 (1993).
  23. G. Kresse and J. Furthmüller, Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set, Phys. Rev. B 54, 11169 (1996).
  24. G. Kresse and J. Furthmüller, Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set, Computational Materials Science 6, 15 (1996).
  25. J. P. Perdew, K. Burke, and M. Ernzerhof, Generalized gradient approximation made simple, Physical Review Letters 77, 3865 (1996).
  26. P. E. Blöchl, Projector augmented-wave method, Physical Review B 50, 17953 (1994).
  27. G. Kresse and D. Joubert, From ultrasoft pseudopotentials to the projector augmented-wave method, Physical Review B 59, 1758 (1999).
  28. https://github.com/Qulacs-Osaka/scikit-qulacs.
  29. F. Ø. Kjeldal and J. J. Eriksen, Decomposing chemical space: Applications to the machine learning of atomic energies, Journal of Chemical Theory and Computation 19, 2029 (2023).
  30. M. Meuwly, Machine learning for chemical reactions, Chemical Reviews 121, 10218 (2021).
  31. T. Shiota, K. Ishihara, and W. Mizukami, Universal neural network potentials as descriptors: Towards scalable chemical property prediction using quantum and classical computers, arXiv preprint arXiv:2402.18433  (2024).
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