Constrained DFT-based magnetic machine-learning potentials for magnetic alloys: a case study of Fe–Al
Permanent link
https://hdl.handle.net/10037/32309Date
2023-11-13Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Tantardini, Christian; Kotykhov, Alexey S.; Gubaev, Konstantin; Hodapp, Max; Shapeev, Alexander V.; Novikov, van S.Abstract
We propose a machine-learning interatomic potential for multi-component magnetic materials. In
this potential we consider magnetic moments as degrees of freedom (features) along with atomic
positions, atomic types, and lattice vectors. We create a training set with constrained DFT (cDFT) that
allows us to calculate energies of confgurations with non-equilibrium (excited) magnetic moments
and, thus, it is possible to construct the training set in a wide confguration space with great variety of
non-equilibrium atomic positions, magnetic moments, and lattice vectors. Such a training set makes
possible to ft reliable potentials that will allow us to predict properties of confgurations in the excited
states (including the ones with non-equilibrium magnetic moments). We verify the trained potentials
on the system of bcc Fe–Al with diferent concentrations of Al and Fe and diferent ways Al and Fe
atoms occupy the supercell sites. Here, we show that the formation energies, the equilibrium lattice
parameters, and the total magnetic moments of the unit cell for diferent Fe–Al structures calculated
with machine-learning potentials are in good correspondence with the ones obtained with DFT. We
also demonstrate that the theoretical calculations conducted in this study qualitatively reproduce the
experimentally-observed anomalous volume-composition dependence in the Fe–Al system.
Publisher
Springer NatureCitation
Tantardini. Constrained DFT-based magnetic machine-learning potentials for magnetic alloys: a case study of Fe–Al. Scientific Reports. 2023;13(1)Metadata
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