Preprint

Inserted: 8 feb 2025
Last Updated: 8 feb 2025

Year: 2025

Abstract:

This paper investigates the existence and qualitative properties of minimizers for a class of nonlocal micromagnetic energy functionals defined on bounded domains. The considered energy functional consists of a symmetric exchange interaction, which penalizes spatial variations in magnetization, and a magnetostatic self-energy term that accounts for long-range dipolar interactions. Motivated by the extension of Brown's fundamental theorem on fine ferromagnetic particles to nonlocal settings, we develop a rigorous variational framework in \( L^2(\Omega ; \mathbb{S}^2) \) under mild assumptions on the interaction kernel \( j \), including symmetry, Lévy-type integrability, and prescribed singular behavior. For spherical domains, we generalize Brown’s fundamental results by identifying critical radii \( R^* \) and \( R^{**} \) that delineate distinct energetic regimes: for \( R \leq R^* \), the uniform magnetization state is energetically preferable (\emph{small-body regime}), whereas for \( R \geq R^{**} \), non-uniform magnetization configurations become dominant (\emph{large-body regime}). These transitions are analyzed through Poincaré-type inequalities and explicit energy comparisons between uniform and vortex-like magnetization states.

Our results directly connect classical micromagnetic theory and contemporary nonlocal models, providing new insights into domain structure formation in nanoscale magnetism. Furthermore, the mathematical framework developed in this work contributes to advancing theoretical foundations for applications in spintronics and data storage technologies.

Keywords: Micromagnetics, nonlocal energies, Brown’s fundamental theorem, Magnetic vortices, Lévy kernels, Single-domain particles

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• Manuscript: DiFratta_Giorgio_Lombardini_Nonlocal_Micromagnetics_Minimizers_and_Brown_Fundamental Theorem