Title :
Thermally induced vortex nucleation in permalloy elements
Author :
Dittrich, R. ; Schrefl, T. ; Kirschner, M. ; Suess, D. ; Hrkac, G. ; Dorfbauer, F. ; Ertl, O. ; Fidler, J.
Author_Institution :
Inst. of Solid State Phys., Vienna Univ. of Technol., Austria
Abstract :
Vortex nucleation and vortex motion are the main mechanisms of magnetization reversal in micrometer-sized magnetic elements. The critical field required to nucleate a vortex depends on the temperature. We propose a method that combines standard Landau-Lifshitz-Gilbert (LLG) micromagnetics and an elastic band method to simulate nonzero temperature hysteresis curves of magnetic thin film elements. Whereas the LLG simulations gives the equilibriums states before and after a vortex enters the element, the elastic band method gives the height of the energy barrier between these two states. Thus temperature-dependent nucleation fields can be computed without the need to perform stochastic LLG simulations.
Keywords :
Landau levels; Permalloy; magnetic thin films; magnetisation reversal; micromagnetics; nucleation; soft magnetic materials; vortices; Landau-Lifshitz-Gilbert micromagnetics; Permalloy; elastic band method; magnetic thin film; magnetization reversal; nonzero temperature hysteresis curves; thermally induced vortex nucleation; vortex motion; Coercive force; Computational modeling; Energy barrier; Fluctuations; Magnetic domains; Magnetic hysteresis; Magnetic switching; Magnetization reversal; Micromagnetics; Temperature; Energy barrier; magnetization reversal; micromagnetics;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2005.854736
