Minimum action paths for spin-torque assisted thermally induced magnetization reversal

We calculate the most probable reaction paths for thermally induced magnetization reversal of a nanomagnet under the influence of spin transfer torque. The presence of the spin transfer torque implies that the standard reaction rate theory of Kramers cannot be used since the dynamics no longer shows...

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Bibliographic Details
Published in:Journal of applied physics 2011-04, Vol.109 (7), p.07C918-07C918-3
Main Authors: Chaves-O'Flynn, Gabriel D., Stein, Daniel L., Kent, Andrew D., Vanden-Eijnden, Eric
Format: Article
Language:English
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Summary:We calculate the most probable reaction paths for thermally induced magnetization reversal of a nanomagnet under the influence of spin transfer torque. The presence of the spin transfer torque implies that the standard reaction rate theory of Kramers cannot be used since the dynamics no longer shows detailed balance and so the magnetization reversals are nonequilibrium transitions. Thin film nanomagnets with a biaxial anisotropy, a shape anisotropy that leads to in-plane magnetization with a preferred axis in the plane, are considered. The reaction pathways and rates are computed using geometrical Minimum Action Method. Our results indicate that the transition state has an out-of-plane magnetization component, in contrast to the case without an applied spin transfer torque.
ISSN:0021-8979
1089-7550
DOI:10.1063/1.3565021