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 at a media facing surface (MFS), a trailing shield at the MFS, and a heavy metal layer disposed between the main pole and the trailing shield at the MFS. Spin-orbit torque (SOT) is generated from the heavy metal layer and transferred to a surface of the main pole as a current passes through the heavy metal layer in a cross-track direction. The SOT executes a torque on the surface magnetization of the main pole, which reduces the magnetic flux shunting from the main pole to the trailing shield. With the reduced magnetic flux shunting from the main pole to the trailing shield, write-ability is improved.

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 at a media facing surface (MFS), a trailing shield at the MFS, and a heavy metal layer disposed between the main pole and the trailing shield at the MFS. Spin-orbit torque (SOT) is generated from the heavy metal layer and transferred to a surface of the main pole as a current passes through the heavy metal layer in a cross-track direction. The SOT executes a torque on the surface magnetization of the main pole, which reduces the magnetic flux shunting from the main pole to the trailing shield. With the reduced magnetic flux shunting from the main pole to the trailing shield, write-ability is improved.

A heat-assisted magnetic recording head includes a write pole tip that extends to a media-facing surface and a heat sink that is thermally coupled to a side of the write pole tip. A surface plasmonic plate is in contact with a side of the heat sink that faces away from the write pole and is recessed from, the media-facing surface. A nanorod extends from a surface of the surface plasmonic plate and towards the media-facing surface.

A heat-assisted magnetic recording head includes a write pole tip that extends to a media-facing surface and a heat sink that is thermally coupled to a side of the write pole tip. A surface plasmonic plate is in contact with a side of the heat sink that faces away from the write pole and is recessed from, the media-facing surface. A nanorod extends from a surface of the surface plasmonic plate and towards the media-facing surface.

Spin transfer torque (STT) devices with multilayer seed layers that can be used in magnetic recording and memory are provided. One such STT device includes a substrate, and a stack of layers formed on the substrate, where the stack includes a first seed layer directly on the substrate and including Cr, a second seed layer on the first seed layer and including Ta, a ferromagnetic free layer on the second seed layer; a ferromagnetic polarizing layer, and a nonmagnetic spacer layer between the free layer and the polarizing layer. One such method includes fabricating the STT device.

An apparatus, according to one embodiment, includes a sensor having an active region, a magnetic shield adjacent the active region, a spacer between the active region and the magnetic shield, a second magnetic shield on an opposite side of the active region as the magnetic shield, and a second spacer between the active region and the second magnetic shield. Both spacers include an electrically conductive ceramic layer. The sensor is an electronic lapping guide.

An apparatus according to one embodiment includes a sensor having an active region, a magnetic shield adjacent the active region, a spacer between the active region and the magnetic shield, a second magnetic shield on an opposite side of the active region as the magnetic shield, and a second spacer between the active region and the second magnetic shield. Both spacers include an electrically conductive ceramic layer. The electrically conductive ceramic layer of the spacer has a different composition than the electrically conductive ceramic layer of the second spacer.

A method includes depositing a magnetic track layer on a seed layer, depositing an alloy layer on the magnetic track layer, depositing a tunnel barrier layer on the alloy layer, depositing a pinning layer on the tunnel barrier layer, depositing a synthetic antiferromagnetic layer spacer on the pinning layer, depositing a pinned layer on the synthetic antiferromagnetic spacer layer and depositing an antiferromagnetic layer on the pinned layer, and another method includes depositing an antiferromagnetic layer on a seed layer, depositing a pinned layer on the antiferromagnetic layer, depositing a synthetic antiferromagnetic layer spacer on the pinned layer, depositing a pinning layer on the synthetic antiferromagnetic layer spacer, depositing a tunnel barrier layer on the pinning layer, depositing an alloy layer on the tunnel barrier layer and depositing a magnetic track layer on alloy layer.

A transducing head having a media-facing surface includes a transducer element, a bottom shield positioned below the transducer element, a heater element positioned below the bottom shield, a heat transfer block positioned below the heater element, and a push block assembly. A first portion of the push block assembly is positioned below a bottom edge of the bottom shield, and a second portion of the push block assembly is located behind the bottom shield relative to the media-facing surface of the transducing head and extends above the bottom edge of the bottom shield, with the first and second portions of the push block assembly spaced from each other. The second portion of the push block assembly overlaps the heater element, and the heater element is positioned between the heat transfer block and at least the second portion of the push block assembly.

A slider has a read transducer comprising first and second shields surrounding a read sensor. The first shield faces a substrate. A first end of the reader stack is at a media-facing surface of the slider and a second end of the reader stack faces away from the first end. A heater is located farther away from the media-facing surface than the second end of the read transducer. The heater is configured to control a thermal protrusion of the read transducer from the media-facing surface. A heat sink is located between the first shield and the substrate.