Network of localized magnetic textures revealed using a saddle-point search framework

TL;DR

This paper introduces a computational framework to systematically identify saddle points in magnetic systems, revealing the transition mechanisms and connectivity of metastable magnetic textures, including topological charge changes.

Contribution

The framework combines symmetry analysis, eigenmode guidance, and geodesic mode following to map the energy landscape of magnetic textures, a novel approach for understanding their transition pathways.

Findings

Revealed hierarchy of transition mechanisms in chiral magnets

Constructed a network of metastable states and transition pathways

Identified topological charge changes during magnetic texture transitions

Abstract

A computational framework is presented for the sampling of the energy surface of magnetic systems via the systematic identification of first-order saddle points that determine connectivity of metastable states and define the mechanisms of transitions between them. The framework combines four stages: first, the symmetry of a given minimum-energy configuration is identified and used to define subsystems whose eigenmodes provide relevant deformation directions; the subsystem eigenmodes are then used to guide the system toward the vicinity of different saddle points surrounding the energy minimum; next, the geodesic minimum mode following method is employed to efficiently converge onto the saddle points; and finally, the identified saddle points are embedded into the state network. Applied to metastable textures in two-dimensional chiral magnets described by a lattice Hamiltonian, the method reveals a hierarchy of transition mechanisms governing the nucleation, annihilation, and rearrangement of the fundamental components of localized magnetic textures. The identified saddle points enable the construction of the network of metastable states, where saddle points define the connectivity between them, providing a comprehensive map of accessible transitions and their associated energy barriers. Transitions corresponding to both homotopies that preserve the topological charge and transformations that change it are identified. By scaling the interaction parameters, the distinct behavior of these two classes is obtained as the continuum limit is approached. Finally, it is shown that textures with the same topological charge are not always connected by a homotopy corresponding to a minimum-energy path: in specific parameter regimes, the total topological charge necessarily increases and then decreases (or vice versa) during the transition, returning to its initial value at the final state.