An apparatus, according to one embodiment, includes: an array of write transducers. Each of the write transducer include: a first write pole having a pole tip extending from a media facing side of the first write pole, and a second write pole having a pole tip extending from a media facing side of the second write pole. Each of the write transducers also include a nonmagnetic write gap between the pole tips of the write poles, a first high moment layer between the write gap and the pole tip of the second write pole, and a second high moment layer between the write gap and the pole tip of the first write pole. The first and second high moment layers each have a higher magnetic moment than magnetic moments of the pole tips of the second and first write poles, respectively.

An apparatus, according to one embodiment, includes: an array of write transducers. Each of the write transducer include: a first write pole having a pole tip extending from a media facing side of the first write pole, and a second write pole having a pole tip extending from a media facing side of the second write pole. Each of the write transducers also include a nonmagnetic write gap between the pole tips of the write poles, a first high moment layer between the write gap and the pole tip of the second write pole, and a second high moment layer between the write gap and the pole tip of the first write pole. The first and second high moment layers each have a higher magnetic moment than magnetic moments of the pole tips of the second and first write poles, respectively.

A system for transition curvature improvement on thermally assisted magnetic recording, includes: an energy source, a thermally assisted magnetic recording head including a magnetic main pole for writing of a thermally assisted magnetic recording medium, a waveguide for directing an energy produced by the energy source, and a PPG including a peg and adjacent to the waveguide, the PPG being for turning the energy into a surface plasmon which travels down the peg to heat the thermally assisted magnetic recording medium. The magnetic main pole includes a first portion enabling a first magnetic field strength and at least one additional portion enabling a magnetic field strength stronger than the first magnetic field strength such that a magnetic field of the magnetic main pole along a horizontal direction thereof enables generation of a substantially straight transition curve while writing on the thermally assisted magnetic recording medium.

A system for transition curvature improvement on thermally assisted magnetic recording, includes: an energy source, a thermally assisted magnetic recording head including a magnetic main pole for writing of a thermally assisted magnetic recording medium, a waveguide for directing an energy produced by the energy source, and a PPG including a peg and adjacent to the waveguide, the PPG being for turning the energy into a surface plasmon which travels down the peg to heat the thermally assisted magnetic recording medium. The magnetic main pole includes a first portion enabling a first magnetic field strength and at least one additional portion enabling a magnetic field strength stronger than the first magnetic field strength such that a magnetic field of the magnetic main pole along a horizontal direction thereof enables generation of a substantially straight transition curve while writing on the thermally assisted magnetic recording medium.

An apparatus, according to one embodiment, includes: write transducers, each having: a first write pole having a pole tip, and a second write pole having a pole tip, the pole tips extending from a media facing side of the respective write pole. The pole tip of the second write pole is configured to emanate magnetic flux directly from the media facing side toward a magnetic medium. Each write transducer has a nonmagnetic write gap between the pole tips of the write poles, and a first high moment layer between the write gap and the pole tip of the second write pole. The first high moment layer has a higher magnetic moment than that of the pole tip of the second write pole. Moreover, the first high moment layer protrudes beyond a plane extending along a media facing side of the pole tips of the first and second write poles.

An apparatus, according to one embodiment, includes: write transducers, each having: a first write pole having a pole tip, and a second write pole having a pole tip, the pole tips extending from a media facing side of the respective write pole. The pole tip of the second write pole is configured to emanate magnetic flux directly from the media facing side toward a magnetic medium. Each write transducer has a nonmagnetic write gap between the pole tips of the write poles, and a first high moment layer between the write gap and the pole tip of the second write pole. The first high moment layer has a higher magnetic moment than that of the pole tip of the second write pole. Moreover, the first high moment layer protrudes beyond a plane extending along a media facing side of the pole tips of the first and second write poles.

A dual PMR writer is disclosed wherein a first main pole (MP1) in writer 1 is a mirror image of a second main pole (MP2) in writer 2 with respect to a center plane aligned orthogonal to the air bearing surface (ABS). MP1 and MP2 may have an asymmetrical top-down shape to reduce writer-writer spacing (WWS) and read write offset (RWO) when a single or double reader is positioned down-track at the center plane. Accordingly, there is less track misregistration and better area density capability. Each of MP1 and MP2 as well as a top yoke (TY), and a tapered bottom yoke (tBY) have a rectangular back portion of width w from 4 to 10 microns. Spacing between MP1 and MP2 back portions may be 4 microns to prevent cross-talk. RWO is reduced from 4 microns for symmetrical TY/MP/tBY shapes to 3 microns or less for asymmetrical shapes.

A dual PMR writer is disclosed wherein a first main pole (MP1) in writer 1 is a mirror image of a second main pole (MP2) in writer 2 with respect to a center plane aligned orthogonal to the air bearing surface (ABS). MP1 and MP2 may have an asymmetrical top-down shape to reduce writer-writer spacing (WWS) and read write offset (RWO) when a single or double reader is positioned down-track at the center plane. Accordingly, there is less track misregistration and better area density capability. Each of MP1 and MP2 as well as a top yoke (TY), and a tapered bottom yoke (tBY) have a rectangular back portion of width w from 4 to 10 microns. Spacing between MP1 and MP2 back portions may be 4 microns to prevent cross-talk. RWO is reduced from 4 microns for symmetrical TY/MP/tBY shapes to 3 microns or less for asymmetrical shapes.

A magnetic recording write head has an electrically-conductive structure in the write gap between the write pole and the trailing shield and electrical circuitry for directing current through the write gap. The current through the electrically-conductive structure generates a circular Ampere field which, at the disk-facing end of the write pole, is substantially parallel to the disk-facing end of the write pole. The electrically-conductive structure in the write gap may be a STO or an electrically-conductive layer that is not part of a STO. The current direction through the electrically-conductive structure in the write gap is selected so that the generated Ampere field at the write pole end is in substantially the same direction as the magnetization direction of the write head side shields, which has been discovered to result in minimization of cross-track interference.

A magnetic recording write head has an electrically-conductive structure in the write gap between the write pole and the trailing shield and electrical circuitry for directing current through the write gap. The current through the electrically-conductive structure generates a circular Ampere field which, at the disk-facing end of the write pole, is substantially parallel to the disk-facing end of the write pole. The electrically-conductive structure in the write gap may be a STO or an electrically-conductive layer that is not part of a STO. The current direction through the electrically-conductive structure in the write gap is selected so that the generated Ampere field at the write pole end is in substantially the same direction as the magnetization direction of the write head side shields, which has been discovered to result in minimization of cross-track interference.