Control of the magnetic hopfion lattice in helimagnet with the external field and anisotropy (2503.23481v2)

Abstract: A generalized micromagnetic model of hopfions in a helimagnet with a two-dimensional (allowing both radial and azimuthal dependence) profile function is considered. Calculations confirm the elliptical stability of hopfions and the previously obtained analytical expression for the upper critical field of their lattice. Dependencies of the hopfion lattice periods on the magnitude of the applied external magnetic field and the uniaxial anisotropy constant of the material are obtained. It is shown that in an anisotropic helimagnet, the hopfion lattice expands in the direction of the anisotropy axis, and the expansion can be controlled by the external field and the uniaxial anisotropy constant.

Magnetic Hopfion Lattice Control in Helimagnets

This paper presents a thorough investigation into the control of magnetic hopfion lattices within helimagnets via external magnetic fields and uniaxial anisotropy. The paper is grounded on a generalized micromagnetic model, extending previous models by accounting for an additional dimension in the hopfion's profile function. The primary focus is on demonstrating the stability, structure, and controllability of hopfion lattices in a bulk magnetic environment.

Background and Theoretical Framework

Hopfions are three-dimensional (3D) topological solitons with complex structures, attracting considerable interest due to advancements in nanoscale observation techniques. Unlike well-known lower-dimensional solitons like skyrmions, hopfions map sphere $S^3$ to $S^2$, introducing intricate topology and potential for applications in 3D spintronics.

The researchers employed a variational model predictive of two classes of hopfions in helimagnets, refining it by introducing a radial and azimuthal dependence in the hopfion profile function. This nuanced model yields a more precise description of hopfion characteristics compared to its predecessors, enabling a detailed exploration of the lattice formed by these solitons.

Results and Observations

The paper confirms the elliptical stability of hopfions and showcases how their lattice configuration can be influenced by external stimuli:

• Elliptical Stability & Spherical Structure: Despite the inclusion of an additional azimuthal profile dimension, hopfions maintain elliptical stability—critical for potential applications. A notable finding is that hopfion cores stay nearly spherical, although their external contours can undergo elliptical deformation.
• Critical Magnetic Field & Anisotropy Effects: The paper delivers a numerical estimate for the upper critical field beyond which hopfion lattices transition to uniform magnetization. The results are congruent with prior analytical results, underscoring the robustness of the theoretical framework. Dependencies of the lattice spacing on the external magnetic field and anisotropy constant were also derived, highlighting the layered, graphite-like structure of the hopfion lattice due to anisotropy.
• Scalability and Layering: External fields uniformly rescale lattice parameters and hopfion sizes, demonstrating a degree of controllability valuable for integration into magnetic materials. Anisotropy leads to height adjustments along the magnetic field direction, promoting distinct layering reminiscent of graphite structures, which might facilitate unique diffraction signatures useful for experimental characterization.

Implications and Future Directions

The conducted research enriches the theoretical landscape for designing magnetic materials incorporating hopfions and offers pathways for experimental verifications using methods like neutronography. Practically, this paper lays a foundation for harnessing hopfions in multi-layered, anisotropic magnetic materials, potentially advancing the quest for new data storage and spintronic devices.

Further exploration could involve experimental validation through nanoscale imaging and attempts to manipulate hopfions in real-world applications, focusing on 3D spintronic environments. Additionally, theoretical advancements could delve into interactions between differing topological solitons, potentially unveiling new magnetic phenomena and functionality in engineered systems.

In summary, the paper's methodological advancements and rigorous analysis of hopfion stability and structure provide a valuable framework that lays the groundwork for future theoretical and experimental exploration in the dynamic field of magnetic solitons and 3D spintronic device engineering.