Title :
Role of Dipolar Interactions on the Thermal Stability of High-Density Bit-Patterned Media
Author :
Eibagi, N. ; Kan, Jimmy J. ; Spada, F.E. ; Fullerton, Eric E.
Author_Institution :
Center for Magn. Recording Res., Univ. of California at San Diego, La Jolla, CA, USA
fDate :
7/4/1905 12:00:00 AM
Abstract :
We have characterized the magnetic reversal and thermal stability of bit-patterned media with a composite structure of [Co (0.25 nm)/Pd (0.7 nm)]5 /Fe(X)/[Pd (0.7 nm)/Co (0.25 nm)] 5, where X = 1, 1.5 , and 2 nm. For 25 nm diameter islands separated by 35 nm, the average thermal stability of the islands is confirmed by analyzing the time-dependent coercive fields. However, by further analyzing the time-dependent hysteresis loop shape, we find a broad distribution of the effective energy barriers. We quantitatively show that this energy barrier distribution arises primarily from the dipolar interactions in these densely packed arrays and not from intrinsic distributions.
Keywords :
cobalt; coercive force; iron; magnetic hysteresis; magnetic moments; magnetic multilayers; palladium; thermal stability; Co-Pd-Fe-Pd-Co; dipolar interaction; energy barrier distribution; high density bit-patterned media; magnetic reversal; thermal stability; time dependent coercive field; time dependent hysteresis loop shape; Energy barrier; Iron; Magnetic hysteresis; Magnetic recording; Media; Switches; Thermal stability; Information storage; bit-patterned media; composite structures; dipolar interactions; energy barrier;
Journal_Title :
Magnetics Letters, IEEE
DOI :
10.1109/LMAG.2012.2211864
