Title :
Linear density dependence of thermal decay in longitudinal recording
Author :
Richter, H.J. ; Brockie, Richard M. ; Pressesky, Jason L.
Author_Institution :
Seagate Recording Media, Fremont, CA, USA
fDate :
1/1/2002 12:00:00 AM
Abstract :
We present experimental and theoretical data on the signal decay of recordings measured at various densities. In contrast to expectations, the signal decay does not generally increase with increasing linear density; rather, it peaks at a surprisingly low density. Using a nondestructive spin-stand technique, we determined the energy barrier as well as the anisotropy field distribution. These experimental data are used in a self-consistent recording model that accounts for thermal activation effects at writing as well as at storage. We found that the record process inevitably induces phase shifts in the recorded pattern that lead to the observed decay behavior
Keywords :
coercive force; demagnetisation; grain size; hard discs; magnetic anisotropy; magnetic recording; magnetisation reversal; superparamagnetism; anisotropy field distribution; energy barrier; generalized dynamic coercivity; intergranular exchange; linear density dependence; longitudinal demagnetizing field; longitudinal recording; magnetic hard disk recording; nondestructive spin-stand technique; percolation effects; phase shifts; self-consistent recording model; signal decay; storage; superparamagnetic limit; thermal activation effects; thermal decay; thermally activated magnetization; two-dimensional isotropic structure; writing; Anisotropic magnetoresistance; Density measurement; Disk recording; Energy barrier; Magnetic anisotropy; Magnetic field measurement; Magnetic recording; Magnetization; Perpendicular magnetic anisotropy; Writing;
Journal_Title :
Magnetics, IEEE Transactions on
