A magnetoresistance element can have a substrate; a ferromagnetic seed layer consisting of a binary alloy of NiFe; and a first nonmagnetic spacer layer disposed under and directly adjacent to the ferromagnetic seed layer and proximate to the substrate, wherein the first nonmagnetic spacer layer is comprised of Ta or Ru. A method fabricating of fabricating a magnetoresistance element can include depositing a seed layer structure over a semiconductor substrate, wherein the depositing the seed layer structure includes depositing at least a ferromagnetic seed layer over the substrate. The method further can further include depositing a free layer structure over the seed layer structure, wherein the depositing the ferromagnetic seed layer comprises depositing the ferromagnetic seed layer in the presence of a motion along a predetermined direction and in the presence of a predetermined magnetic field having the same predetermined direction.

A giant magnetoresistance (GMR) element is provided for use in a magnetic multi-turn sensor in which the free layer, that is, the layer that changes its magnetization direction in response to an external magnetic field so as to provide a resistance change, is thick enough to provide good shape anisotropy without exhibiting an AMR effect. To achieve this, at least a portion of the free layer comprises a plurality of layers of at least two different materials, specifically, a plurality of layers of at least a first material that is ferromagnetic and a plurality of layers of at least a second material that is known not to exhibit an AMR effect and that does not interfere with the GMR effect of the layers of ferromagnetic material.

Provided is a non-ferromagnetic spacing composite layer, comprising first, second and third spacing layers stacked in sequence. The first and third spacing layers are each made of Re, Rh, Ir, W, Mo, Ta, or Nb, and the second spacing layer is made of Ru. The second spacing layer has a thickness of equal to or more than 0.18 nm, and the non-ferromagnetic spacing composite layer has a total thickness of 0.6 nm to 1 nm. Also, provided are a method of preparing the non-ferromagnetic spacing composite layer, a synthetic antiferromagnetic laminated structure, and an MRAM. The synthetic antiferromagnetic laminated structure can maintain a certain coupling strength and the RKKY indirect interaction after thermal treatment, thereby keeping the recording function of MRAM.

A magnetic structure is provided. The magnetic structure may have a first magnetic layer with a first magnetization direction, a second magnetic layer with a second magnetization direction and a coupling layer interposed between the first and second magnetic layers. The coupling layer may include at least one non-magnetic element and at least one magnetic element. The atomic ratio of the at least one non-magnetic element to the at least one magnetic element is (100−x):x, where x is an atomic concentration parameter. Atomic concentration parameter, x, may cause the first magnetic layer to be non-collinearly coupled to the second magnetic layer such that, in the absence of external magnetic field, the first magnetization direction is oriented at a non-collinear angle relative to the second magnetization direction.

A magnetoresistive device with a magnetically fixed region having at least two ferromagnetic regions coupled together by an antiferromagnetic coupling region. At least one of the two ferromagnetic regions includes multiple alternating metal layers and magnetic layers and one or more interfacial layers. Wherein, each metal layer includes at least one of platinum, palladium, nickel, or gold, and the interfacial layers include at least one of an oxide, iron, or an alloy including cobalt and iron.

A magnetic structure is provided. The magnetic structure may have a first magnetic layer with a first magnetization direction, a second magnetic layer with a second magnetization direction and a coupling layer interposed between the first and second magnetic layers. The coupling layer may include at least one non-magnetic element and at least one magnetic element. The atomic ratio of the at least one non-magnetic element to the at least one magnetic element is (100-x):x, where x is an atomic concentration parameter. Atomic concentration parameter, x, may cause the first magnetic layer to be non-collinearly coupled to the second magnetic layer such that, in the absence of external magnetic field, the first magnetization direction is oriented at a non-collinear angle relative to the second magnetization direction.

A thin film magnet includes a substrate, an oxidation-inhibiting layer in an amorphous state disposed on an upper surface of the substrate, a first magnetic layer disposed on the oxidation-inhibiting layer, an intermediate layer disposed on the first magnetic layer, a second magnetic layer disposed on the intermediate layer, and a second oxidation-inhibiting layer in an amorphous state disposed above the second magnetic layer. The intermediate layer contains metal particles. The metal particles are diffused in the first magnetic layer and the second magnetic layer. The concentration of the metal particles in a part of the first magnetic layer decreases as the distance from the intermediate layer to the part of the first magnetic layer increases. The concentration of the metal particles in a part of the second magnetic layer decreases as the distance from the intermediate layer to the part of the second magnetic layer increases.

A magnetoresistive device with a magnetically fixed region having at least two ferromagnetic regions coupled together by an antiferromagnetic coupling region. At least one of the two ferromagnetic regions includes multiple alternating metal layers and magnetic layers and one or more interfacial layers. Wherein, each metal layer includes at least one of platinum, palladium, nickel, or gold, and the interfacial layers include at least one of an oxide, iron, or an alloy including cobalt and iron.

A magnetoresistance element has a pinning arrangement with two antiferromagnetic pinning layers, two pinned layers, and a free layer. A spacer layer between one of the two antiferromagnetic pinning layers and the free layer has a material selected to allow a controllable partial pinning by the one of the two antiferromagnetic pinning layers.

A magnetoresistance element has a pinning arrangement with two antiferromagnetic pinning layers, two pinned layers, and a free layer. A spacer layer between one of the two antiferromagnetic pinning layers and the free layer has a material selected to allow a controllable partial pinning by the one of the two antiferromagnetic pinning layers.