Title :
Granular thin films with high RF permeability
Author :
Shimada, Yutaka ; Yamaguchi, Masahiro ; Ohnuma, Sigehiro ; Itoh, Tetsuo ; Li, Wei Dong ; Ikeda, Sinji ; Kim, Ki Hyeon ; Nagura, H.
Author_Institution :
Inst. of Multidisciplinary Res. for Adv. Mater., Tohoku Univ., Sendai, Japan
Abstract :
Owing to high resistivity and high inplane uniaxial anisotropy, granular films are known to exhibit high permeability at radio frequencies. But this granular resistivity is not high enough to suppress eddy current when they are used at gigahertz frequencies. Recent developments to solve this problem are described. One is patterning the granular films. It is effective to control the inplane anisotropy and to suppress inplane eddy current. Another is deposition of granular films by evaporation. A peculiar fiber structure is formed for which very high resistivity and anisotropy are realized. Finally, a study of using these films as near-field electromagnetic noise absorbers is described, and it is demonstrated that they have high potential as micrometer-scale noise absorbing elements in the gigahertz frequency range.
Keywords :
eddy currents; electrical resistivity; ferromagnetic materials; granular materials; interference suppression; magnetic anisotropy; magnetic permeability; magnetic thin films; radiofrequency interference; soft magnetic materials; Co-Zr-O; Co56Al18O26; Co60Zr11O29; Co85Nb11Zr4; Fe-Al-O; Fe70(ZrO2)30; deposition; eddy current; evaporation; ferromagnetic particles; fine ferromagnetic crystals; gigahertz frequencies; granular resistivity; granular thin films; high RF permeability; high inplane uniaxial anisotropy; high resistivity; inplane anisotropy; magnetic softness; micrometer-scale noise absorbing elements; near-field electromagnetic noise absorbers; oxide matrix; patterning; peculiar fiber structure; Anisotropic magnetoresistance; Conductivity; Electromagnetic interference; Iron; Magnetic anisotropy; Magnetic films; Magnetic materials; Permeability; Radio frequency; Transistors;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2003.815892
