According to one embodiment, a magnetic memory device includes a first magnetic portion, a first electrode, a second electrode, a third electrode, a second magnetic portion, a first nonmagnetic portion, and a controller. The first magnetic portion includes an extension portion and a third portion. The extension portion includes a first portion and a second portion. The third portion is connected to the second portion. The first electrode is electrically connected to the first portion. At least a portion of the third portion is positioned between the second electrode and the third electrode. The second magnetic portion is provided between the second electrode and the at least a portion of the third portion. The first nonmagnetic portion is provided between the second magnetic portion and the at least a portion of the third portion. The controller is electrically connected to the first, second electrode, and third electrodes.

The disclosed technology generally relates to magnetic devices, and more particularly to magnetic devices configured to generate a stream of domain walls propagating along an output magnetic bus. In an aspect, a magnetic device includes a magnetic propagation layer, which in turn includes a plurality of magnetic buses. The magnetic buses include an output magnetic bus configured to guide propagating magnetic domain walls. The magnetic propagation layer further comprises a central region in which the magnetic buses converge and are joined together. The magnetic buses include at least a first and a second magnetic bus having opposite magnetization orientations with respect to each other, such that a domain wall separating the opposite magnetization states is pinned in the central region. In another aspect, a method includes providing the magnetic device and generating the stream of domain walls propagating along the output magnetic bus by applying spin orbit and/or transfer torques to the pinned domain wall to alternate the pinned domain wall between two stable configurations, in which each stable configuration corresponds to a different magnetization state of the output magnetic bus in at least a region where the output magnetic bus is joined to the central region.

A storage device includes: a memory unit and a first pillar. The first pillar includes: a first region having a third portion between a first and a second portion respectively having a first and a second maximum diameter, and having a first minimum diameter, the first and second portions defining a first distance; a second region having a sixth portion between a fourth and a fifth portion respectively having a third and a fourth maximum diameter, and having a second minimum diameter, the fourth and fifth portions defining a second distance; and a third region between the first and second regions, having a ninth portion between a seventh and an eighth portion respectively having a fifth and a sixth maximum diameter, and having a third minimum diameter, the seventh and eighth portions defining a third distance shorter than each of the first and second distances.

A method of forming a memory device having magnetic tracks individually comprising a plurality of magnetic domains having domain walls, includes forming an elevationally outer substrate material of uniform chemical composition. The uniform composition material is partially etched into to form alternating regions of elevational depressions and elevational protrusions in the uniform composition material. A plurality of magnetic tracks is formed over and which angle relative to the alternating regions. Interfaces of immediately adjacent of the regions individually form a domain wall pinning site in individual of the magnetic tracks. Other methods, including memory devices independent of method, are disclosed.

A magnetic wall utilization spin MOSFET includes a magnetic wall driving layer including a magnetic wall, a first region, a second region, and a third region located between the first region and the second region, a channel layer, a magnetization free layer provided at a first end portion of a first surface of the channel layer, and arranged so as to be in contact with the third region of the magnetic wall driving layer, a magnetization fixed layer provided at a second end portion opposite to the first end portion, and a gate electrode provided between the first end portion and the second end portion of the channel layer through a gate insulating layer.

A method of forming a memory device having magnetic tracks individually comprising a plurality of magnetic domains having domain walls, includes forming an elevationally outer substrate material of uniform chemical composition. The uniform composition material is partially etched into to form alternating regions of elevational depressions and elevational protrusions in the uniform composition material. A plurality of magnetic tracks is formed over and which angle relative to the alternating regions. Interfaces of immediately adjacent of the regions individually form a domain wall pinning site in individual of the magnetic tracks. Other methods, including memory devices independent of method, are disclosed.

Provided is a magnetic element capable of generating one skyrmion and erasing the one skyrmion. The magnetic element includes a magnet shaped like a substantially rectangular flat plate, an upstream electrode connected to the magnet in a width Wm direction of the magnet and made of a non-magnetic metal, a downstream electrode connected to the magnet in the width Wm direction to oppose the upstream electrode and made of a non-magnetic metal, and a skyrmion sensor configured to detect the skyrmion. Here, a width Wm of the substantially rectangular magnet is such that 3.Math.?>Wm??, where ? denotes a diameter of the skyrmion, a length Hm of the substantially rectangular magnet is such that 2.Math.?>Hm??, and the magnet has a notch structure at the edge between the upstream electrode and the downstream electrode.

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.

According to one embodiment, a magnetic memory element comprises a first magnetic unit, a second magnetic unit, a first insulating unit, a first electrode, a second electrode, and a third electrode. The first magnetic unit includes a plurality of magnetic domains. The second magnetic unit includes a first region and a second region. The first region includes a conductive material. The second region includes an insulating material. At least one of the first region or the second region is magnetic. The first insulating unit is provided between the first magnetic unit and the second magnetic unit. The first electrode and the second electrode are connected to the first magnetic unit. A part of the second magnetic unit and a part of the first insulating unit are provided between the third electrode and a part of the first magnetic unit.

The disclosed technology generally relates to magnetic devices, and more particularly to magnetic devices configured to generate a stream of domain walls propagating along an output magnetic bus. In an aspect, a magnetic device includes a magnetic propagation layer, which in turn includes a plurality of magnetic buses. The magnetic buses include an output magnetic bus configured to guide propagating magnetic domain walls. The magnetic propagation layer further comprises a central region in which the magnetic buses converge and are joined together. The magnetic buses include at least a first and a second magnetic bus having opposite magnetization orientations with respect to each other, such that a domain wall separating the opposite magnetization states is pinned in the central region. In another aspect, a method includes providing the magnetic device and generating the stream of domain walls propagating along the output magnetic bus by applying spin orbit and/or transfer torques to the pinned domain wall to alternate the pinned domain wall between two stable configurations, in which each stable configuration corresponds to a different magnetization state of the output magnetic bus in at least a region where the output magnetic bus is joined to the central region.