Key role of temperature in ferromagnetic Bloch point simulations | Zendy

K. M. Lebecki | Zendy; D. Hinzke | Zendy; U. Nowak | Zendy; O. ChubykaloFesenko | Zendy

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Key role of temperature in ferromagnetic Bloch point simulations

Author(s) -

K. M. Lebecki,

D. Hinzke,

U. Nowak,

O. ChubykaloFesenko

Publication year - 2012

Publication title -

physical review b

Language(s) - English

Resource type - Journals

eISSN - 1538-4489

pISSN - 1098-0121

DOI - 10.1103/physrevb.86.094409

Subject(s) - bloch equations , condensed matter physics , bloch wave , physics , gravitational singularity , micromagnetics , ferromagnetism , point (geometry) , radius , bloch oscillations , magnetization , quantum mechanics , geometry , magnetic field , mathematics , computer security , computer science , superlattice

Bloch points in permalloy cylinders are investigated using a micromagnetic framework, where thermal effects are included via the Landau-Lifshitz-Bloch equation of motion. We show that this enables micromagnetic modeling of a Bloch point avoiding the problem of singularities, which have been rep0l1ed in the literature so far. The details of the Bloch point which we reveal are compared with earlier analytic approximations describing its geometry and the magnetization drop in its center. The temperature dependence of characteristic parameters, like the Bloch point radius or the azimuthal inflow angle is given in the full temperature range.

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