Title :
Fe-simulation of fast switching behavior of granular nanoelements
Author :
Fidler, J. ; Schrefl, T. ; Tsiantos, V.D. ; Forster, H. ; Suess, D. ; Scholz, W. ; Dittrich, R.
Author_Institution :
Inst. of Appl. & Tech. Phys., Vienna Univ. of Technol., Austria
Abstract :
Summary form only given. Magnetic switching of mesoscopic and nanostructured thin film elements becomes increasingly important in magnetic storage, microsensors and magneto electronic devices. The switching fields and times which are in the order of pico- to nanoseconds are controlled by the choice of the geometric shape and microstructure of the nanomagnets, the intrinsic properties and the orientation and strength of the applied field. Detailed distribution of the magnetization inside the nanoelements is obtained through numerical integration of the Landau-Lifshitz Gilbert equation of motion. The present study is the first micromagnetic simulation taking into account the granular microstructure of the films.
Keywords :
boundary-elements methods; cobalt; ferromagnetic materials; finite element analysis; iron; iron alloys; magnetic particles; magnetic switching; magnetic thin films; magnetisation; micromagnetics; nanostructured materials; nickel alloys; Co; Fe; Landau-Lifshitz Gilbert equation; NiFe; boundary element method; fast switching behavior; finite element method; geometric shape; granular microstructure; granular nanoelements; magnetic switching; magnetization; micromagnetic simulation; microstructure; nanomagnets; numerical integration; Magnetic devices; Magnetic films; Magnetic memory; Magnetic switching; Magnetization; Microsensors; Microstructure; Nanoscale devices; Shape control; Thin film devices;
Conference_Titel :
Magnetics Conference, 2002. INTERMAG Europe 2002. Digest of Technical Papers. 2002 IEEE International
Conference_Location :
Amsterdam, The Netherlands
Print_ISBN :
0-7803-7365-0
DOI :
10.1109/INTMAG.2002.1001510
