Machine Learning Force-Field Approach for Itinerant Electron Magnets
This work provides a method for dynamical modeling of spin orders in spintronics, but it is incremental as it builds on existing group-theoretical approaches.
The authors tackled the problem of simulating complex spin dynamics in itinerant electron magnets by developing a machine-learning force-field framework based on symmetry-invariant representations, demonstrating successful reproduction of non-collinear spin structures and revealing freezing dynamics and glassy stripe states in large-scale thermal quench simulations.
We review the recent development of machine-learning (ML) force-field frameworks for Landau-Lifshitz-Gilbert (LLG) dynamics simulations of itinerant electron magnets, focusing on the general theory and implementations of symmetry-invariant representations of spin configurations. The crucial properties that such magnetic descriptors must satisfy are differentiability with respect to spin rotations and invariance to both lattice point-group symmetry and internal spin rotation symmetry. We propose an efficient implementation based on the concept of reference irreducible representations, modified from the group-theoretical power-spectrum and bispectrum methods. The ML framework is demonstrated using the s-d models, which are widely applied in spintronics research. We show that LLG simulations based on local fields predicted by the trained ML models successfully reproduce representative non-collinear spin structures, including 120$^\circ$, tetrahedral, and skyrmion crystal orders of the triangular-lattice s-d models. Large-scale thermal quench simulations enabled by ML models further reveal intriguing freezing dynamics and glassy stripe states consisting of skyrmions and bi-merons. Our work highlights the utility of ML force-field approach to dynamical modeling of complex spin orders in itinerant electron magnets.