The effect of an applied magnetic field on the complex permeability of a hexagonal ferrite

Author

Bush, G.G.

Author_Institution

Lockheed Missiles & Space Co. Inc., Palo Alto, CA

Volume

25

Issue

5

fYear

1989

fDate

9/1/1989 12:00:00 AM

Firstpage

4222

Lastpage

4223

Abstract

The complex permeabilities of ferrites with spinel, garnet, and hexagonal crystal structure have been measured as a function of frequency and applied magnetic field. A simple phenomenological theory derived from J.F. Snoek´s (1948) limit concept has been applied as a guide to the behavior of these ferrites as controllable magnetic materials. The crystal structure has not proved to be a good predictor of permeability dependence on applied magnetic fields. Rotational resonance and significant cubic anisotropy are useful indicators of controllable behavior. The existence of substantially modifiable magnetic materials such as barium ferrite and YIG that exhibit control behavior suggests the feasibility of molecular design of materials in the 100-MHz to 3-GHz frequency range

Keywords

barium compounds; ferrimagnetic properties of substances; ferrites; garnets; magnetic permeability measurement; 100 to 3000 MHz; BaFe₁₂O₁₉; Snoek´s limit; YFe5O12; YIG; applied magnetic field; complex permeabilities; controllable magnetic materials; crystal structure; cubic anisotropy; feasibility; function of frequency; garnet crystal structure; garnets; hexagonal crystal structure; hexagonal ferrite; modifiable magnetic materials; molecular design of materials; permeability dependence; phenomenological theory; spinel crystal structure; Anisotropic magnetoresistance; Barium; Ferrites; Frequency measurement; Garnets; Magnetic field measurement; Magnetic fields; Magnetic materials; Magnetic resonance; Permeability measurement;

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/20.42575

Filename

42575