A device including a first magnetic layer, a templating structure and a second magnetic layer is described. The templating structure is on the first magnetic layer. The second magnetic layer is on the templating structure. The templating structure includes D and E. A ratio of D to E is represented by D.sub.1-xE.sub.x, with x being at least 0.4 and not more than 0.6. E includes a main constituent. The main constituent includes at least one of Al, Ga, and Ge. E includes at least fifty atomic percent of the main constituent. D includes at least one constituent that includes Ir. D includes at least 50 atomic percent of the at least one constituent. The templating structure is nonmagnetic at room temperature. At least one of the first magnetic layer and the second magnetic layer includes at least one of a Heusler compound and an L1.sub.0 compound.

A magnetic memory according to an embodiment includes: a magnetic member including a first to third magnetic parts, the first magnetic part including a first portion and a second portion and extending in a first direction from the first portion to the second portion, the second magnetic part extending in a second direction that crosses the first direction, and the third magnetic part connecting the second magnetic part and the first portion; a first nonmagnetic metal layer arranged along the third magnetic part, the first nonmagnetic metal layer including a first end portion on a side of the second portion, a position of the first end portion along the first direction being between positions of the first and second portions along the first direction; and a first and second electrodes supplying a current between the first and second magnetic parts via the third magnetic part.

A magnetic memory device includes a first magnetic layer extending in a first direction, a second magnetic layer that extends on and parallel to the first magnetic layer, and a conductive layer extending between the first magnetic layer and the second magnetic layer. The first magnetic layer includes a first region having magnetic moments oriented in a first rotational direction along the first direction. The second magnetic layer includes a second region having magnetic moments oriented in a second rotational direction along the first direction. The second rotational direction is different from the first rotational direction.

A race track magnetic memory device includes a magnetic fine wire having a plurality of magnetic domains, a magnetic tunnel junction element comprising a pinned layer and an insulating layer, and a spin-orbit torque (SOT) generator. An easy axis of the magnetic fine wire is substantially perpendicular to a contact surface of the magnetic fine wire and the SOT generator. The magnetic tunnel junction element and the SOT generator are disposed on a magnetic domain write region of the magnetic fine wire. Data is written by generating spin-transfer torque at magnetization of the magnetic domain write region by flowing a first current in the magnetic tunnel junction element and by generating spin-orbit torque at the magnetization of the magnetic domain write region by flowing a second current in the SOT generator.

A magnetic memory device includes a first magnetic structure having a magnetic anisotropy, a read electrode that is on an end of the first magnetic structure and configured to sense a first magnetic moment of the first magnetic structure and to convert the first magnetic moment to an electric signal, a second magnetic structure spaced apart from the first magnetic structure, the second magnetic structure having a magnetic anisotropy, and a write electrode that is on an end of the second magnetic structure and configured to change a second magnetic moment of the second magnetic structure, based on the electric signal. The magnetic memory device executes operations of writing, moving, and reading data on almost the entire region of the magnetic structure in a more efficient manner, compared with the conventional magnetic memory device.

A magnetic domain wall movement element according to the present embodiment includes a magnetoresistance effect element that has a reference layer, a nonmagnetic layer, and a magnetic domain wall movement layer in order from a side closer to a substrate; and a first magnetization fixed layer and a second magnetization fixed layer which are each in contact with the magnetic domain wall movement layer and are separated from each other, wherein the magnetic domain wall movement layer includes a plurality of ferromagnetic layers and a plurality of insertion layers sandwiched between the plurality of ferromagnetic layers, wherein the ferromagnetic layer contains Co and Fe and has perpendicular magnetic anisotropy, and wherein, when writing is performed, a write current is allowed to flow between the first magnetization fixed layer and the second magnetization fixed layer along the magnetic domain wall movement layer.

A switching device according to an embodiment includes a switching layer disposed between a first electrode and a second electrode. The switching layer contains a material containing a first cation element Z, Te, and N. This material contains at least 5 atomic % or more of each of Z, Te, and N, and when an atomic ratio of Te is X, an atomic ratio of N is Y, an atomic ratio of Z is W, a ratio of Z.sub.2Te.sub.3 to ZN on a straight line connecting a compound of the first cation element Z with tellurium and nitride of the first cation element Z in a ternary phase diagram of Z, Te, and N is A, and a change in an N content from the Z.sub.2Te.sub.3-ZN line is B, the material has a composition satisfying X=1.2 (1−A) (0.5+B), Y=A (0.5+B), and W=1−X−Y, where −0.06≤B≤0.06 is satisfied when ⅓>A and ¾<A, and −0.06≤B and Y≤0.45 are satisfied when ⅓≤A≤¾.

According to one embodiment, a magnetic memory includes a magnetic body with two portions of a first dimension in a first direction which are spaced from each other a second direction and another portion that has a second dimension less than the first dimension in the first direction, which is between the two other portions. A circuit supplies a shift pulse to the magnetic body. The shift pulse includes a first pulse and a second pulse and moves a domain wall in the magnetic body along the second direction. The first pulse has a first pulse width. The second pulse has a second pulse width less than the first pulse width. The second pulse is supplied to the magnetic body after the first pulse.

A magnetic storage device includes a magnetic body including first and second magnetic regions and a magnetic connection region that connects the first and second magnetic regions, and in which a plurality of magnetic domains each storing information by a magnetization direction thereof is formed, a read element that is electrically connected to the magnetic connection region and by which a magnetization direction of one of the magnetic domains is read, and a write element by which a magnetic domain having a magnetization direction is formed in the magnetic body according to information to be stored. The magnetic domains formed in each of the first and second magnetic regions are shifted in a predetermined direction in response to current that flows through the corresponding one of the first and second magnetic regions.

According to one embodiment, a memory system includes a shift register memory and a controller. The shift register memory includes data storing shift strings. The controller changes a shift pulse, which is to be applied to the data storing shift strings from which first data is read by applying a first shift pulse, to a second shift pulse to write second data to the data storing shift strings and to read the second data from the data storing shift strings. The controller creates likelihood information of data read from the data storing shift strings in accordance with a read result of the second data. The controller performs soft decision decoding for the first data using the likelihood information.