Title :
Switching of magnetostrictive micro-dot arrays by mechanical strain
Author :
Bootsmann, M.-T. ; Dokupil, S. ; Quandt, E. ; Ivanov, T. ; Abedinov, N. Caesar ; Löhndorf, M.
Author_Institution :
Center of Adv. Eur. Studies & Res., Bonn, Germany
Abstract :
This paper investigates the switching behavior of magnetostrictive micro-dot arrays by mechanical strain. These amorphous FeCoBSi micro-dot arrays with diameters of 1-5 μm and a thickness of 20 nm have been prepared on MEMS fabricated membrane structures. Magnetic force microscopy (MFM) has been used to obtain a spatially resolved switching behavior of these dots at different level of mechanical strain. For 20-nm-thick FeCoBSi dots, we have observed a strain induced switching starting at a level of about 0.04% of strain. In addition, finite-element simulations have been performed in order to correlate the MFM results with the local strain distribution of the membrane structure.
Keywords :
boron alloys; cobalt alloys; ferromagnetic materials; finite element analysis; iron alloys; magnetic force microscopy; magnetisation; magnetostrictive devices; micromechanical devices; silicon alloys; strain sensors; 1 to 5 micron; 20 nm; FeCoBSi; MEMS; finite element simulations; magnetic force microscopy; magnetostrictive micro-dot array switching; mechanical strain; membrane structures; Amorphous magnetic materials; Amorphous materials; Biomembranes; Magnetic field induced strain; Magnetic force microscopy; Magnetic forces; Magnetic switching; Magnetostriction; Micromechanical devices; Spatial resolution; Magnetostriction; micro-fabrication; strain sensors; thin films;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2005.854747
