Title :
Hybrid recording features and material candidates beyond Tera bit/in/sup 2/
Author :
Ota, N. ; Matsunuma, S. ; Takeuchi, T. ; Daimon, H. ; Inaba, N. ; Awano, H.
Author_Institution :
R&D Div., Hitachi Maxell Ltd., Ibaraki, Japan
Abstract :
Magnetic recording will face very serious problems beyond Tera bit/in/sup 2/, such as: recorded bit thermal stability in a size range of less than 20 nm×30 nm; very strong magnetic field necessary to write on a high coercive media, estimated over 15 kOe; write frequency limited to a few GHz, depending on the natural resonance of the magnetic material. In a hybrid recording scheme, writing is done at a high temperature around 150-230 °C, while archiving at room temperature. Such a simple concept brings solutions to solve the above difficulties. This paper outlines various hybrid recording device configurations and checks out the applicability of several materials for this type of application.
Keywords :
coercive force; magnetic resonance; thermal stability; thermomagnetic recording; 150 to 230 degC; 20 degC; 20 nm; 30 nm; CoPtCr; FePt; Pd-Co; TbFeCo; high coercive media; high temperature hybrid recording schemes; hybrid magnetic recording features/materials; hybrid recording device configurations; magnetic material natural resonance; recorded bit size range; recorded bit thermal stability; room temperature archiving; write frequency; write magnetic fields; Amorphous magnetic materials; Frequency estimation; Inorganic materials; Magnetic domains; Magnetic films; Magnetic materials; Magnetic recording; Optical materials; Soft magnetic materials; Temperature;
Conference_Titel :
Joint NAPMRC 2003. Digest of Technical Papers [Perpendicular Magnetic Recording Conference]
Conference_Location :
Monterey, CA, USA
Print_ISBN :
0-7803-7746-X
DOI :
10.1109/NAPMRC.2003.1177069
