Abstract: A spin valve thin-film magnetic element has an improved rate of change in resistance (&Dgr;R/R) that can be used for a narrower magnetic track. The spin valve thin-film magnetic element has a laminate that include an antiferromagnetic layer, a pinned magnetic layer, a non-magnetic conductive layer, a free magnetic layer, a back layer, specular-reflection layers and a pair of electrode layers formed at the two sides of the laminate. Preferably the specular reflection layer includes an oxide, such as &agr;-Fe2O3 or NiO, or a half-metal Heusler alloy, such as NiMnSb or PtMnSb.

Abstract: The present invention provides a spin valve thin film magnetic element including a laminate in which an antiferromagnetic layer, a pinned magnetic layer provided in contact with the antiferromagnetic layer so that the magnetization direction is pinned by an exchange coupling magnetic field with the antiferromagnetic layer, a nonmagnetic conductive layer provided in contact with the pinned magnetic layer, a second free magnetic layer provided in contact with the nonmagnetic conductive layer, a nonmagnetic intermediate layer provided in contact with the second free magnetic layer, a first free magnetic layer provided in contact with the nonmagnetic intermediate layer and antiferromagnetically coupled with the second free magnetic layer to form a ferrimagnetic state together with the second free magnetic layer, and a backed layer provided in contact with the first free magnetic layer and having higher conductivity than the first free magnetic layer are laminated.

Abstract: A longitudinal bias layer and an electrode layer are formed on a non-magnetic material layer. The longitudinal bias layer and the electrode layer are partially removed by an etching technique so that a narrow gap defining the track width Tw is formed in the longitudinal bias layer and the electrode layer. Furthermore, a three-layer film consisting of, from bottom to top, a magnetoresistance effect layer, a non-magnetic layer, and a transverse bias layer, or otherwise a spin valve film consisting of a free magnetic layer, a non-magnetic layer, a fixed magnetic layer and a bias layer is formed on the above structure. The three-layer film or the spin valve film is then partially removed by an etching technique so that the three-layer film or the spin valve film remains only in the above-described narrow gap formed in the longitudinal bias layer and the electrode layer.

Abstract: A spin-valve thin-film magnetic element includes a substrate, a composite formed thereon, and electrode layers formed on both sides of the composite. The composite includes an antiferromagnetic layer, a pinned magnetic layer, a nonmagnetic conductive layer, a free magnetic layer, a mean-free-path-extending layer, and an exchange bias layer. The mean-free-path-extending layer may be a back layer or a mirror reflective layer. The mean-free-path-extending layer extends the mean free path of spin-up conduction electrons in the spin-valve thin-film magnetic element. This spin-valve thin-film magnetic element meets trends toward a narrower track width.

Abstract: A thin-film magnetic head includes a spin-valve thin-film magnetic element, first and second insulating layers, and first and second shielding layers. The spin-valve thin-film magnetic element includes a free magnetic layer, a nonmagnetic conductive layer, a pinned magnetic layer, an antiferromagnetic layer, a pair of bias layers, and a pair of conductive layers. The pair of conductive layers is located on one side in the thickness direction of the free magnetic layer, and the pair of bias layers is located on the other side in the thickness direction of the free magnetic layer, is disposed on both sides in the track width direction of at least a portion of the second insulating layer, and is in contact with the free magnetic layer.

Abstract: A magnetoresistive element includes an insulating layer formed between electrode layers, and the electrode layers are formed on a multilayer film so as to be in contact with the sides of the insulating layer. The thickness of the electrode layers can therefore be kept thick even at front end faces and a sensing current can flow into the multilayer film always at a constant level.

Abstract: Both of decreasing the direct current resistance and flattening of the top face of the element can be simultaneously attained by forming a first lead layer under the bottom side of a laminated body as well as by reducing the film thickness of a second lead layer located at both sides of the laminated body. Excessive signals from outside of the area of the track width Tw are not picked up during regeneration operation since the width of the laminated body is adjusted to be nearly equal to the track width Tw thereby enabling to attain a good regenerative characteristic.

Abstract: A longitudinal bias layer and an electrode layer are formed on a non-magnetic material layer. The longitudinal bias layer and the electrode layer are partially removed by an etching technique so that a narrow gap defining the track width Tw is formed in the longitudinal bias layer and the electrode layer. Furthermore, a three-layer film consisting of, from bottom to top, a magnetoresistance effect layer, a non-magnetic layer, and a transverse bias layer, or otherwise a spin valve film consisting of a free magnetic layer, a non-magnetic layer, a fixed magnetic layer and a bias layer is formed on the above structure. The three-layer film or the spin valve film is then partially removed by an etching technique so that the three-layer film or the spin valve film remains only in the above-described narrow gap formed in the longitudinal bias layer and the electrode layer.

Abstract: A spin-valve magnetoresistive element comprises an antiferromagnetic layer, a pinned magnetic layer, a nonmagnetic electrically conductive layer and a free magnetic layer formed in that order, and biasing layers formed on both sides of at least the free magnetic layer, the magnetization vector in the pinned magnetic layer being fixed by exchange anisotropic coupling with the antiferromagnetic layer, the biasing layers unifying the magnetization vector in the free magnetic layer in a direction perpendicular to the magnetization vector in the pinned magnetic layer, and a conductive path conducting a sensing current to the pinned magnetic layer, the nonmagnetic electrically conductive layer and the free magnetic layer. The antiferromagnetic layer extends to outer regions on both sides of the pinned magnetic layer, the nonmagnetic layer and the free magnetic layer. The biasing layers are formed on the antiferromagnetic layer.

Abstract: A longitudinal bias layer and an electrode layer are formed on a non-magnetic material layer. The longitudinal bias layer and the electrode layer are partially removed by an etching technique so that a narrow gap defining the track width Tw is formed in the longitudinal bias layer and the electrode layer. Furthermore, a three-layer film consisting of, from bottom to top, a magnetoresistance effect layer, a non-magnetic layer, and a transverse bias layer, or otherwise a spin valve film consisting of a free magnetic layer, a non-magnetic layer, a fixed magnetic layer and a bias layer is formed on the above structure. The three-layer film or the spin valve film is then partially removed by an etching technique so that the three-layer film or the spin valve film remains only in the above-described narrow gap formed in the longitudinal bias layer and the electrode layer.