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3 Gb/in super(2) recording demonstration with dual element heads & thin film disks

We have successfully demonstrated magnetic recording at an areal density of 3 Gb/in super(2) with narrow track inductive-write MR-read dual element heads on low noise Co alloy thin film disks. In this demonstration, the write head is a ten turn thin film inductive head with thick and narrow P2 pole-...

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Bibliographic Details
Published in:IEEE transactions on magnetics 1996-01, Vol.32 (1), p.7-12
Main Authors: Tsang, Ching, Santini, Hugo, McCown, Don, Lo, Jerry, Lee, Rod
Format: Article
Language:English
Online Access:Get full text
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Summary:We have successfully demonstrated magnetic recording at an areal density of 3 Gb/in super(2) with narrow track inductive-write MR-read dual element heads on low noise Co alloy thin film disks. In this demonstration, the write head is a ten turn thin film inductive head with thick and narrow P2 pole-tips. The read head is a shielded approximately 1 mu m trackwidth MR sensor soft-film biased in the read region for linearization and exchange-biased at the tail regions for magnetic stabilization. During recording tests, the heads were flown over low noise Co-alloy media at a clearance similar to that in the previous 1 Gb/in super(2) recording experiment. Results showed good writability from the narrow track write head in terms of overwrite and hard transition shift. Readback yields symmetrical signals as large as 600 mu V (p-p) and rolloff measurements showed 50% densities as high as 5000 fc/mm. Track profile and microtrack profile measurements showed the write and read trackwidths to be approximately 1.4 mu m and approximately 1.1 mu m respectively, with tight side-writing and side-reading characteristics. An overall assessment of the parametric recording results suggested areal density feasibility up to as high as 3 Gb/in super(2). This projection was confirmed by error rate performance testing using a PRML channel with a digital filter and write precompensation. At a data rate of 4-5 Mb/s and at very low ontrack error, a linear density as high as 185 Kbpi and an optimized track pitch as narrow as 1.5 mu m were achieved, corresponding to an areal recording density of approximately 3.1 Gb/in super(2).
ISSN:0018-9464