Title :
Media for erasable magnetooptic recording
Author :
Hansen, Peter ; Heitmann, Heinrich
Author_Institution :
Philips GmbH Forschungslab., Hamburg, West Germany
fDate :
11/1/1989 12:00:00 AM
Abstract :
Amorphous rare-earth-transition-metal alloys are considered as materials for magnetooptic information storage. They can be prepared by evaporation or sputtering on glass or polymer substrates. The alloys are ferrimagnets and exhibit a uniaxial magnetic anisotropy. The magnetic and magnetooptic properties can be well tailored by the composition as well as the deposition conditions. The information is stored by memory magnetic domains which can be written by a thermomagnetic switching process. The reading process utilizes the magnetooptic Kerr effect. In both cases the temperature profile of the saturation magnetization, the uniaxial anisotropy, and in particular the coercivity are of primary importance. At present, the most prominent candidates for device applications are GdTb-FeCo and Tb-FeCo alloys. Carrier-to-noise values up to 61 dB (30 kHz) have been achieved using magnetooptic disks
Keywords :
Kerr magneto-optical effect; cobalt alloys; coercive force; ferrimagnetic properties of substances; gadolinium alloys; iron alloys; magnetic anisotropy; magnetic domains; magnetic thin films; magnetisation; magneto-optical recording; sputtered coatings; terbium alloys; vapour deposited coatings; 30 kHz; GdTb-FeCo; Tb-FeCo alloys; amorphous rare-earth-transition-metal alloys; carrier-to-noise ratio; coercivity; erasable magnetooptic recording; evaporation deposition; ferrimagnets; glass substrate; magnetooptic Kerr effect; magnetooptic disks; magnetooptic information storage; memory magnetic domains; polymer substrates; reading process; saturation magnetization; sputtering; temperature profile; thermomagnetic switching process; uniaxial magnetic anisotropy; Amorphous magnetic materials; Amorphous materials; Magnetic anisotropy; Magnetic domains; Magnetic materials; Magnetooptic devices; Magnetooptic effects; Magnetooptic recording; Material storage; Saturation magnetization;
Journal_Title :
Magnetics, IEEE Transactions on
