npj Computational Materials (Nov 2021)

Exploring DFT+U parameter space with a Bayesian calibration assisted by Markov chain Monte Carlo sampling

  • Pedram Tavadze,
  • Reese Boucher,
  • Guillermo Avendaño-Franco,
  • Keenan X. Kocan,
  • Sobhit Singh,
  • Viviana Dovale-Farelo,
  • Wilfredo Ibarra-Hernández,
  • Matthew B. Johnson,
  • David S. Mebane,
  • Aldo H. Romero

DOI
https://doi.org/10.1038/s41524-021-00651-0
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 9

Abstract

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Abstract The density-functional theory is widely used to predict the physical properties of materials. However, it usually fails for strongly correlated materials. A popular solution is to use the Hubbard correction to treat strongly correlated electronic states. Unfortunately, the values of the Hubbard U and J parameters are initially unknown, and they can vary from one material to another. In this semi-empirical study, we explore the U and J parameter space of a group of iron-based compounds to simultaneously improve the prediction of physical properties (volume, magnetic moment, and bandgap). We used a Bayesian calibration assisted by Markov chain Monte Carlo sampling for three different exchange-correlation functionals (LDA, PBE, and PBEsol). We found that LDA requires the largest U correction. PBE has the smallest standard deviation and its U and J parameters are the most transferable to other iron-based compounds. Lastly, PBE predicts lattice parameters reasonably well without the Hubbard correction.