Title :
Low-temperature annealing effect on plasma sprayed MnZn ferrite for planar transformers of high-frequency applications
Author :
Yan, Q.Y. ; Gambino, R.J. ; Sampath, S.
Author_Institution :
Mater. Sci. & Eng. Dept., Stony Brook Univ., NY, USA
Abstract :
MnZn ferrite coatings fabricated by plasma spray have the advantage of a columnar structure with average grain size between 200-300 nm, somewhat analogous to that of conventional laminated cores used to minimize the eddy current loss at high frequency. The resistivity of these ferrite coatings increases by four orders of magnitude after a simple annealing process at 500°C in air. Our studies reveal that this change is due to oxygen diffusion through the grain boundaries, which results in the oxidation of Fe2+ to Fe3+ and inhibits the "hopping" conductivity effect between Fe2+ and Fe3+. The initial permeability at 100 kHz increases from around 500 to above 1000. This change is believed to be due to the local- and long-range redistribution of Mn and Zn, which improves the soft magnetic properties of the ferrite coatings.
Keywords :
annealing; eddy current losses; ferrites; grain boundary diffusion; grain size; hopping conduction; magnetic permeability; magnetic thin films; manganese compounds; plasma arc sprayed coatings; soft magnetic materials; zinc compounds; 100 kHz; 200 to 300 nm; 500 degC; Fe2+; Fe3+; MnZn ferrite coatings; MnZnFe2O4; annealing process; average grain size; columnar structure; eddy current loss; ferrite coatings; grain boundaries; high frequency; high-frequency applications; hopping conductivity; initial permeability; low-temperature annealing effect; oxidation; oxygen diffusion; planar transformers; plasma spray; plasma sprayed MnZn ferrite; resistivity; soft magnetic properties; Annealing; Coatings; Conductivity; Eddy currents; Ferrites; Grain size; Iron; Plasma applications; Thermal spraying; Transformer cores;
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2003.816020
