Abstract
We have formulated a relaxation mechanism for ferrites and ferromagnets (insulators and metals) whereby the coupling between the magnetic motion and lattice is based purely on continuum arguments concerning magnetostriction. This theoretical approach contrasts with previous mechanisms based on microscopic formulations of spin-phonon interactions employing a discrete lattice. Our model explains the scaling of the intrinsic ferromagnetic resonance linewidth with frequency, with temperature { ∝1/Ms(T)} and the anisotropic nature of magnetic relaxation in ordered magnetic materials. Here, Ms(T) is the thermal saturation magnetization. Without introducing adjustable parameters, our model is in reasonable quantitative agreement with experimental measurements of the intrinsic magnetic resonance linewidths of important class of ordered magnetic materials including both insulators and metals.
Keywords
relaxation mechanism, ferromagnets, insulators, metals, magnetic motion, magnetic lattice, thermal saturation magnetization
Subject Categories
Ferrites (Magnetic materials), Magnetostriction, Ferromagnetic resonance
Disciplines
Electromagnetics and photonics
Publisher
American Physical Society
Publication Date
1-1-2010
Rights Information
Copyright 2010 American Physical Society
Rights Holder
American Physical Society
Permanent URL
Recommended Citation
Vittoria, C.; Yoon, S. D.; and Widom, A., "Relaxation mechanism for ordered magnetic materials" (2010). Electrical and Computer Engineering Faculty Publications. Paper 114. http://hdl.handle.net/2047/d20002285
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Notes
Originally published in Physical Review B 81, 014412 (2010). doi 10.1103/PhysRevB81.014412 (http://link.aps.org/doi/10.1103/PhysRevB81.014412).