Abstract: An exchange-coupled film includes a antiferromagnetic layer and a pinned magnetic layer including a ferromagnetic layer stacked together, the antiferromagnetic layer having a structure including an IrMn layer, a first PtMn layer, a PtCr layer, and a second PtMn layer stacked in that order, the IrMn layer being in contact with the pinned magnetic layer. The second PtMn layer preferably has a thickness of more than 0 ? and less than 60 ?, in some cases. The PtCr layer preferably has a thickness of 100 ? or more, in some cases. The antiferromagnetic layer preferably has a total thickness of 200 ? or less, in some cases.

Abstract: A position detection element includes an exchange coupling film having a large exchange coupling magnetic field and a position detection apparatus showing good detection accuracy in a high temperature environment. The position detection element includes an exchange coupling film composed of a fixed magnetic layer and an antiferromagnetic layer stacked on the fixed magnetic layer. The antiferromagnetic layer includes an X(Cr—Mn) layer containing X that is one or more elements selected from the group consisting of platinum group metals and Ni and containing Mn and Cr. The X(Cr—Mn) layer includes a PtMn layer as a first region relatively closer to the fixed magnetic layer and a PtCr layer as a second region relatively farther from the fixed magnetic layer. The content of Mn in the first region is higher than the content of Mn in the second region.

Abstract: In an exchange coupling film that has a large magnetic field (Hex) in which the direction of magnetization of a fixed magnetic layer is reversed, high stability under high temperature conditions, and excellent strong-magnetic field resistance, an antiferromagnetic layer, a fixed magnetic layer, and a free magnetic layer are stacked, the antiferromagnetic layer is composed of a PtCr layer and an XMn layer (where X is Pt or Ir), the XMn layer is in contact with the fixed magnetic layer, and the fixed magnetic layer is made of iron, cobalt, an iron-cobalt alloy, or an iron-nickel alloy.

Abstract: An exchange coupling film in which a magnetic field (Hex) at which the magnetization direction of a pinned magnetic layer is reversed is high, in which stability under high-temperature conditions is high, and which is excellent in strong-magnetic field resistance. The exchange coupling film includes an antiferromagnetic layer and a pinned magnetic layer including a ferromagnetic layer, the antiferromagnetic layer and the pinned magnetic layer being stacked together. The antiferromagnetic layer has a structure including a PtCr layer, a PtMn layer, and an IrMn layer stacked in this order. The IrMn layer is in contact with the pinned magnetic layer. The thickness of the PtMn layer is 12 ? or more, and the thickness of the IrMn layer is 6 ?. The sum of the thickness of the PtMn layer and the thickness of the IrMn layer is 20 ? or more.

Abstract: A tunnel magnetoresistance effect (TMR) device includes an exchange coupling film having a first ferromagnetic layer, which is at least a portion of a fixed magnetic layer, and an antiferromagnetic layer laminated on the first ferromagnetic layer. The ferromagnetic layer includes an X(Cr—Mn) layer containing one or two or more elements X selected from the group consisting of the platinum group elements and Ni, and also containing Mn and Cr. The X(Cr—Mn) layer has a first region relatively near the first ferromagnetic layer, and a second region relatively far away from the first ferromagnetic layer, and the content of Mn in the first region is higher than that in the second region.

Abstract: An exchange-coupling film having a large magnetic field (Hex) at which the magnetization direction of a pinned magnetic layer is reversed, thus exhibiting high stability under high-temperature conditions, and having excellent high-magnetic-field resistance includes an antiferromagnetic layer and a pinned magnetic layer in contact with the antiferromagnetic layer. The antiferromagnetic layer has an alternating multilayer structure of three or more layers, the layers including alternately stacked X1Cr and X2Mn layers, where X1 represents one or more elements selected from the group consisting of platinum group elements and Ni, and X2 represents one or more elements selected from the group consisting of platinum group elements and Ni and may be the same as or different from X1.

Abstract: A magnetic detector includes a full-bridge circuit including magnetoresistive sensors on the same substrate. The magnetoresistive sensors include two magnetoresistive films and have different relationships between the fixed magnetization direction and the bias application direction. The fixed magnetization direction and the bias application direction are determined with three or more exchange coupling films including antiferromagnetic layers with different blocking temperatures. Thus, the magnetic detector has high resistance to a strong magnetic field, is easy to produce, and has a high degree of flexibility in production.

Abstract: A magnetic-field-applying bias film exhibiting resistance to a high magnetic field has an exchange-coupled film including a permanent magnet layer and an antiferromagnetic layer stacked on the permanent magnet layer. The antiferromagnetic layer includes an X(Cr—Mn) layer containing Cr, Mn, and one or two or more elements selected from the group consisting of platinum-group elements and Ni. The X(Cr—Mn) layer has a first region relatively near to the permanent magnet layer and a second region relatively distant from the permanent magnet layer. Mn content in the first region is higher than Mn content in the second region.

Abstract: A magnetic-field-applying bias film having strong-magnetic-field resistance includes an exchange coupling film. The exchange coupling film includes a ferromagnetic layer and an antiferromagnetic layer stacked on the ferromagnetic layer. The antiferromagnetic layer includes an X(Cr—Mn) layer containing Mn, Cr, and one or more elements X selected from the group consisting of platinum-group elements and Ni. The X(Cr—Mn) layer has a first region relatively close to the ferromagnetic layer and a second region relatively far from the ferromagnetic layer. The Mn content in the first region is higher than the Mn content in the second region.

Abstract: A magnetic detector includes a full-bridge circuit including magnetoresistive sensors on the same substrate. The magnetoresistive sensors include two magnetoresistive films and have different relationships between the fixed magnetization direction and the bias application direction. The fixed magnetization direction and the bias application direction are determined with three or more exchange coupling films including antiferromagnetic layers with different blocking temperatures. Thus, the magnetic detector has high resistance to a strong magnetic field, is easy to produce, and has a high degree of flexibility in production.

Abstract: An exchange-coupled film includes a antiferromagnetic layer and a pinned magnetic layer including a ferromagnetic layer stacked together, the antiferromagnetic layer having a structure including an IrMn layer, a first PtMn layer, a PtCr layer, and a second PtMn layer stacked in that order, the IrMn layer being in contact with the pinned magnetic layer. The second PtMn layer preferably has a thickness of more than 0 ? and less than 60 ?, in some cases. The PtCr layer preferably has a thickness of 100 ? or more, in some cases. The antiferromagnetic layer preferably has a total thickness of 200 ? or less, in some cases.

Abstract: A magnetic detector includes a full-bridge circuit including magnetoresistive sensors on the same substrate. The magnetoresistive sensors include two magnetoresistive films and have different relationships between the fixed magnetization direction and the bias application direction. The fixed magnetization direction and the bias application direction are determined with three or more exchange coupling films including antiferromagnetic layers with different blocking temperatures. Thus, the magnetic detector has high resistance to a strong magnetic field, is easy to produce, and has a high degree of flexibility in production.

Abstract: A magnetic detector includes a full-bridge circuit including magnetoresistive sensors on the same substrate. The magnetoresistive sensors include two magnetoresistive films and have different relationships between the fixed magnetization direction and the bias application direction. The fixed magnetization direction and the bias application direction are determined with three or more exchange coupling films including antiferromagnetic layers with different blocking temperatures. Thus, the magnetic detector has high resistance to a strong magnetic field, is easy to produce, and has a high degree of flexibility in production.

Abstract: A tunnel magnetoresistance effect (TMR) device includes an exchange coupling film having a first ferromagnetic layer, which is at least a portion of a fixed magnetic layer, and an antiferromagnetic layer laminated on the first ferromagnetic layer. The ferromagnetic layer includes an X(Cr—Mn) layer containing one or two or more elements X selected from the group consisting of the platinum group elements and Ni, and also containing Mn and Cr. The X(Cr—Mn) layer has a first region relatively near the first ferromagnetic layer, and a second region relatively far away from the first ferromagnetic layer, and the content of Mn in the first region is higher than that in the second region.

Abstract: A position detection element includes an exchange coupling film having a large exchange coupling magnetic field and a position detection apparatus showing good detection accuracy in a high temperature environment. The position detection element includes an exchange coupling film composed of a fixed magnetic layer and an antiferromagnetic layer stacked on the fixed magnetic layer. The antiferromagnetic layer includes an X(Cr—Mn) layer containing X that is one or more elements selected from the group consisting of platinum group metals and Ni and containing Mn and Cr. The X(Cr—Mn) layer includes a PtMn layer as a first region relatively closer to the fixed magnetic layer and a PtCr layer as a second region relatively farther from the fixed magnetic layer. The content of Mn in the first region is higher than the content of Mn in the second region.

Abstract: A magnetic-field-applying bias film having strong-magnetic-field resistance includes an exchange coupling film. The exchange coupling film includes a ferromagnetic layer and an antiferromagnetic layer stacked on the ferromagnetic layer. The antiferromagnetic layer includes an X(Cr—Mn) layer containing Mn, Cr, and one or more elements X selected from the group consisting of platinum-group elements and Ni. The X(Cr—Mn) layer has a first region relatively close to the ferromagnetic layer and a second region relatively far from the ferromagnetic layer. The Mn content in the first region is higher than the Mn content in the second region.

Abstract: A magnetic-field-applying bias film exhibiting resistance to a high magnetic field has an exchange-coupled film including a permanent magnet layer and an antiferromagnetic layer stacked on the permanent magnet layer. The antiferromagnetic layer includes an X(Cr—Mn) layer containing Cr, Mn, and one or two or more elements selected from the group consisting of platinum-group elements and Ni. The X(Cr—Mn) layer has a first region relatively near to the permanent magnet layer and a second region relatively distant from the permanent magnet layer. Mn content in the first region is higher than Mn content in the second region.

Abstract: An exchange-coupling film having a large magnetic field (Hex) at which the magnetization direction of a pinned magnetic layer is reversed, thus exhibiting high stability under high-temperature conditions, and having excellent high-magnetic-field resistance includes an antiferromagnetic layer and a pinned magnetic layer in contact with the antiferromagnetic layer. The antiferromagnetic layer has an alternating multilayer structure of three or more layers, the layers including alternately stacked X1Cr and X2Mn layers, where X1 represents one or more elements selected from the group consisting of platinum group elements and Ni, and X2 represents one or more elements selected from the group consisting of platinum group elements and Ni and may be the same as or different from X1.

Abstract: In an exchange coupling film that has a large magnetic field (Hex) in which the direction of magnetization of a fixed magnetic layer is reversed, high stability under high temperature conditions, and excellent strong-magnetic field resistance, an antiferromagnetic layer, a fixed magnetic layer, and a free magnetic layer are stacked, the antiferromagnetic layer is composed of a PtCr layer and an XMn layer (where X is Pt or Ir), the XMn layer is in contact with the fixed magnetic layer, and the fixed magnetic layer is made of iron, cobalt, an iron-cobalt alloy, or an iron-nickel alloy.

Abstract: An exchange coupling film in which a magnetic field (Hex) at which the magnetization direction of a pinned magnetic layer is reversed is high, in which stability under high-temperature conditions is high, and which is excellent in strong-magnetic field resistance. The exchange coupling film includes an antiferromagnetic layer and a pinned magnetic layer including a ferromagnetic layer, the antiferromagnetic layer and the pinned magnetic layer being stacked together. The antiferromagnetic layer has a structure including a PtCr layer, a PtMn layer, and an IrMn layer stacked in this order. The IrMn layer is in contact with the pinned magnetic layer. The thickness of the PtMn layer is 12 ? or more, and the thickness of the IrMn layer is 6 ?. The sum of the thickness of the PtMn layer and the thickness of the IrMn layer is 20 ? or more.