Impact of planar defects on the reversal time of single magnetic domain nanoparticles
Abstract
Recent experimental investigations of individual magnetic nanoparticles reveal a diverse range of magnetic relaxation times which cannot be explained by considering their size, shape, and surface anisotropy, suggesting other factors associated with the internal microstructure of the particles are at play. In this letter, we apply Langer's theory of thermal activation to single magnetic domain fcc Co nanoparticles, whose experimental microstructures are characterized by planar defects, and derive an analytic expression for the relaxation time. The obtained Arrhenius exponential and its prefactor, which is often assumed to be a constant, are here found to both depend exponentially on system size and the number of defects. Together they provide a quantitative prediction of the experimental findings, and more generally highlight the importance of structural defects when considering magnetic stability.
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