A dual PMR writer is disclosed wherein the better of the two writers on a slider is integrated into a head gimbal assembly to improve area density capability mean and sigma values, and the other writer is disabled. Each of a driving coil (DC) and bucking coil (BC) have two outer portions that form a U shape with a front side, and have a center portion connected to each of the two outer portions with a narrow arm in which direct current resistance (DCR) is enhanced during a write process. As a result, when writer (coil) induced write gap (WG) protrusion is overlaid on the dynamic fly height (DFH) protrusion profile, the net WG protrusion profile has a maximum value at a cross-track position aligned with a main pole tip in the better writer thereby substantially minimizing magnetic spacing loss compared with conventional dual PMR writers.

The present disclosure generally relates to data storage devices, and more specifically, to a magnetic media drive employing a magnetic recording head. The head includes a main pole, a heavy metal structure surrounding at least a portion of the main pole at a media facing surface (MFS), and two magnetic structures sandwiching the heavy metal structure. Spin-orbit torque (SOT) is generated from the heavy metal structure, inducing magnetization switching (or precession) in the magnetic structures. The SOT reduces the magnetic flux shunting from the main pole to the trailing shield, and the magnetization switching sharpens the write field profile in the cross-track direction. The SOT based head with the magnetic structures sandwiching the heavy metal structure increases both track density (tracks per inch) and linear density (bit per inch), which in turn increases the areal density capability (ADC), which is the product of tracks per inch and bit per inch.

According to one embodiment, a disk-like magnetic recording medium includes a disk-like substrate, a first soft magnetic layer provided on the disk-substrate, a nonmagnetic spacer layer provided on the first soft magnetic layer, a second soft magnetic layer provided on the nonmagnetic spacer layer and antiferromagnetically exchange-coupled with the first soft magnetic layer via the nonmagnetic spacer layer, a magnetic recording layer provided on the second soft magnetic layer, wherein strength of an exchange coupling magnetic field Hbias decreases from an inner circumferential area toward an outer circumferential area of the disk-like magnetic recording medium.

A product according to one embodiment includes a tape having an applicator portion for applying an organic coating to a magnetic head; the organic coating on the applicator portion of the tape; and a lubricant on a data portion of the tape. The lubricant has a different composition than the organic coating. A method for protecting a magnetic head according to one embodiment includes applying an organic coating to a magnetic head using the foregoing product.

A magnetic storage system according to one embodiment includes a magnetic head having a removable organic coating thereon in an amount sufficient for reducing exposure of the head to oxidation promoting materials. The system also includes an applicator in a drive in which the magnetic head resides, the applicator being configured to apply the organic coating directly to the magnetic head without contacting the magnetic head. At least one guide is configured to create a spacing between the magnetic head and the guide, wherein the spacing is sufficient to insert the applicator into the spacing.

A method for protecting a magnetic head according to one embodiment includes applying an organic coating to a magnetic head using a product having an applicator portion for applying an organic coating to a magnetic head. The organic coating is on the applicator portion of the tape, and a lubricant is on a data portion of the tape. The lubricant has a different composition than the organic coating. Another method for protecting a magnetic head includes applying an organic coating to a magnetic head for reducing exposure of the head to oxidation promoting materials; and storing the magnetic head. Another method includes fabricating a tape having an applicator portion for applying an organic coating to a magnetic head for reducing exposure of the head to oxidation promoting materials; applying the organic coating to the applicator portion of the tape; and applying a lubricant to a data portion of the tape.

The present invention relates to an electromagnetic data storage device comprising a data storage medium including a magnetic material, and a write head including an electromagnetic element operable to generate a magnetic field that impinges on a selected portion of the magnetic material of the data storage medium adjacent the write head, so as to affect the magnetization direction of the selected portion of magnetic material. The electromagnetic element includes a magnetic structure including a matrix material, and a plurality of magnetic nanoparticles held in the matrix material.

Disclosed herein is a magnetic write head comprising a main pole, a write gap over the main pole, a first hot seed layer over the main pole, wherein the first hot seed layer comprises a first hot seed material having a first anisotropy value, and a second hot seed layer comprising a second hot seed material having a second anisotropy value, the second anisotropy value being greater than the first anisotropy value, wherein at least a portion of the second hot seed layer is adjacent to the first hot seed layer to mitigate adjacent track interference. Also disclosed are methods to fabricate magnetic write heads having first and second hot seed layers.