Abstract: A magnetic field detecting element has a first lower layer, a second lower layer, a tunnel barrier layer, and an upper layer, wherein the first lower layer, the second lower layer, the tunnel barrier layer, and the upper layer are stacked adjacent to each other in this order, the first lower layer is formed in an amorphous state; and the second lower layer is made of cobalt, iron, nickel or a combination thereof and that is formed in a substantially amorphous state, the second lower layer being in touch with the first lower layer and the tunnel barrier layer on both sides and a film thickness of the second lower layer is approximately between 0.2 and 1.5 nm.

Abstract: A noise-testing method for a thin-film magnetic head with an MR read head element and a heating unit capable of applying a heat and a stress to the MR read head element, includes a step of applying alternately and discontinuously with each other an electrical power having a first level and an electrical power having a second level higher than the first level to the heating unit, and a step of evaluating the thin-film magnetic head by measuring a noise output or noise outputs obtained from the MR read head element when the electrical power or the electrical powers are applied to the heating unit.

Abstract: An MR element incorporates a layered structure. The layered structure includes: a spacer layer having a first surface and a second surface that face toward opposite directions; a free layer disposed adjacent to the first surface of the spacer layer and having a direction of magnetization that changes in response to a signal magnetic field; and a pinned layer disposed adjacent to the second surface of the spacer layer and having a fixed direction of magnetization. The spacer layer is a layer at least part of which is made of a material other than a conductor, and the spacer layer intercepts the passage of currents or limits the passage of currents as compared with a layer entirely made of a conductor. The MR element further incorporates a conductive film that is disposed on the peripheral surface of the layered structure and allows conduction between the free layer and the pinned layer.

Abstract: Provided is a thin-film magnetic head in which a noise due to the voltage potential difference between the read head element and the protective coat surface is suppressed. The thin-film magnetic head comprises: a read head element, one end surface of the read head element reaching an head end surface on the ABS side; a protective coat formed on the head end surface in such a way to cover at least the one end surface of the read head element; and at least one antistatic means for preventing the protective coat from being electrostatically charged, formed on/above the element formation surface, one end surface of the at least one antistatic means reaching the head end surface, the protective coat covering a portion, not the whole, of the one end surface of the at least one antistatic means on the head end surface.

Abstract: An exchange-coupling film incorporates an antiferromagnetic layer and a pinned layer. The pinned layer includes a first ferromagnetic layer, a second ferromagnetic layer, a third ferromagnetic layer, a nonmagnetic middle layer, and a fourth ferromagnetic layer that are disposed in this order, the first ferromagnetic layer being closest to the antiferromagnetic layer. The first ferromagnetic layer is made of a ferromagnetic material and has a face-centered cubic structure. The second ferromagnetic layer is made of only iron or an alloy containing x atomic % cobalt and (100?x) atomic % iron, wherein x is greater than zero and smaller than or equal to 60. The third ferromagnetic layer is made of an alloy containing y atomic % cobalt and (100?y) atomic % iron, wherein y is within a range of 65 to 80 inclusive. The antiferromagnetic layer and the first ferromagnetic layer are exchange-coupled to each other. The third and fourth ferromagnetic layers are antiferromagnetically coupled to each other.

Abstract: A magneto-resistive element has a lower layer, a tunnel barrier layer, and an upper layer. The lower layer, the tunnel barrier layer, and the upper layer are disposed adjacent to each other and are stacked in this order. A magnetization direction of either of the lower layer and the upper layer is fixed relative to an external magnetic field, and a magnetization direction of the other layer is variable in accordance with the external magnetic field. A crystalline portion and a non-crystalline portion co-exist in a plane that is parallel with a surface of the tunnel barrier layer.

Abstract: A testing method of a thin-film magnetic head has an MR read head element with a multi-layered structure including a magnetization-fixed layer, a magnetization-free layer and a nonmagnetic intermediate layer or a tunnel barrier layer sandwiched between the magnetization-fixed layer and the magnetization-free layer. The method includes a step of feeding through the MR read head element a sense current, a step of measuring non-signal output versus frequency characteristics of the MR read head element over a frequency range that covers at least FMR of the magnetization-fixed layer, and a step of discriminating whether the thin-film magnetic head is a head providing high-temperature noises by comparing a frequency of a peak of the non-signal output resulting from FMR of the magnetization-fixed layer with a threshold.

Abstract: A noise-testing method for a thin-film magnetic head with an MR read head element and a heating unit capable of applying a heat and a stress to the MR read head element, includes a step of applying alternately and discontinuously with each other an electrical power having a first level and an electrical power having a second level higher than the first level to the heating unit, and a step of evaluating the thin-film magnetic head by measuring a noise output or noise outputs obtained from the MR read head element when the electrical power or the electrical powers are applied to the heating unit.

Abstract: A testing method of a thin-film magnetic head has an MR read head element with a multi-layered structure including a magnetization-fixed layer, a magnetization-free layer and a nonmagnetic intermediate layer or a tunnel barrier layer sandwiched between the magnetization-fixed layer and the magnetization-free layer. The method includes a step of feeding through the MR read head element a sense current, a step of measuring non-signal output versus frequency characteristics of the MR read head element over a frequency range that covers at least FMR of the magnetization-fixed layer, and a step of discriminating whether the thin-film magnetic head is a head providing high-temperature noises by comparing a frequency of a peak of the non-signal output resulting from FMR of the magnetization-fixed layer with a threshold.

Abstract: Provided is a TMR effect element having no special structures needing much man-hour cost for the formation, in which the high temperature noise and the low temperature noise are suppressed and a sufficiently high resistance-change ratio is provided. The TMR effect element comprises: a tunnel barrier layer formed by oxidizing a base film; and two ferromagnetic layers stacked so as to sandwich the tunnel barrier layer, the base film having a film thickness larger than a film thickness at which a resistance-change ratio of the TMR effect element indicates a maximum value. Here, in the case that the base film is an aluminum film, the film thickness of the aluminum film is preferably in the range of 0.50 nm to 1.5 nm.

Abstract: Provided is a thin-film magnetic head in which a noise due to the voltage potential difference between the read head element and the protective coat surface is suppressed. The thin-film magnetic head comprises: a read head element, one end surface of the read head element reaching an head end surface on the ABS side; a protective coat formed on the head end surface in such a way to cover at least the one end surface of the read head element; and at least one antistatic means for preventing the protective coat from being electrostatically charged, formed on/above the element formation surface, one end surface of the at least one antistatic means reaching the head end surface, the protective coat covering a portion, not the whole, of the one end surface of the at least one antistatic means on the head end surface.

Abstract: A processing condition obtaining method obtains a processing condition that makes it possible to form an extremely thin film of a desired thickness.

Abstract: An MR element comprises: a tunnel barrier layer having two surfaces that face toward opposite directions; a free layer disposed adjacent to one of the surfaces of the tunnel barrier layer and having a direction of magnetization that changes in response to an external magnetic field; and a pinned layer that is a ferromagnetic layer disposed adjacent to the other of the surfaces of the tunnel barrier layer and having a fixed direction of magnetization. The free layer incorporates: a first soft magnetic layer disposed adjacent to the one of the surfaces of the tunnel barrier layer; a high polarization layer disposed such that the first soft magnetic layer is sandwiched between the tunnel barrier layer and the high polarization layer; and a second soft magnetic layer disposed such that the high polarization layer is sandwiched between the first and second soft magnetic layers.

Abstract: An exchange-coupling film incorporates an antiferromagnetic layer and a pinned layer. The pinned layer includes a first ferromagnetic layer, a second ferromagnetic layer, a third ferromagnetic layer, a nonmagnetic middle layer, and a fourth ferromagnetic layer that are disposed in this order, the first ferromagnetic layer being closest to the antiferromagnetic layer. The first ferromagnetic layer is made of a ferromagnetic material and has a face-centered cubic structure. The second ferromagnetic layer is made of only iron or an alloy containing x atomic % cobalt and (100?x) atomic % iron, wherein x is greater than zero and smaller than or equal to 60. The third ferromagnetic layer is made of an alloy containing y atomic % cobalt and (100?y) atomic % iron, wherein y is within a range of 65 to 80 inclusive. The antiferromagnetic layer and the first ferromagnetic layer are exchange-coupled to each other. The third and fourth ferromagnetic layers are antiferromagnetically coupled to each other.

Abstract: An MR element incorporates a layered structure. The layered structure includes: a spacer layer having a first surface and a second surface that face toward opposite directions; a free layer disposed adjacent to the first surface of the spacer layer and having a direction of magnetization that changes in response to a signal magnetic field; and a pinned layer disposed adjacent to the second surface of the spacer layer and having a fixed direction of magnetization. The spacer layer is a layer at least part of which is made of a material other than a conductor, and the spacer layer intercepts the passage of currents or limits the passage of currents as compared with a layer entirely made of a conductor. The MR element further incorporates a conductive film that is disposed on the peripheral surface of the layered structure and allows conduction between the free layer and the pinned layer.

Abstract: A manufacturing method of a TMR element having a magnetization fixed layer, a magnetization free layer and a tunnel barrier layer sandwiched between the magnetization fixed layer and the magnetization free layer. A fabricating process of the tunnel barrier layer includes a step of depositing a first metallic material film on the magnetization fixed layer or the magnetization free layer, and a step of oxidizing the deposited first metallic material film under an environment with an impurity concentration of 1E-02 or less.

Abstract: A manufacturing method of a TMR element having a tunnel barrier layer sandwiched between lower and upper ferromagnetic layers. A fabricating process of the tunnel barrier layer includes a step of depositing a first metallic material film on the lower ferromagnetic layer, a step of oxidizing the deposited first metallic material film using an oxygen gas with a first pressure, a step of depositing a second metallic material film of the same material as that of the first metallic film or of metallic material containing primarily the same material as that of the first metallic film, on the oxidized first metallic film, and a step of oxidizing the deposited second metallic material film using an oxygen gas with a second pressure that is lower than the first pressure.

Abstract: A magneto-resistive device is provided for contributing to a higher MR ratio and a reduced cleaning time for cleaning the surface of a cap layer. In the magneto-resistive device, a cap layer which serves as a protection layer is formed on a free layer which is the topmost layer of a magneto-resistive layer constituting a TMR devise. An upper electrode which is additionally used as an upper magnetic shield is electrically connected to the free layer through an upper metal layer. The cap layer comprised of a two-layer film made up of a conductive layer closer to the free layer and a topmost conductive layer. The conductive layer closer to the free layer is made of a material having higher oxygen bond energy than Ru, such as Zr, Hf, or the like. The topmost conductive layer is made of a material having lower oxygen bond energy, such as a noble metal or the like.

Abstract: A magneto-resistive element has a lower layer, a tunnel barrier layer, and an upper layer. The lower layer, the tunnel barrier layer, and the upper layer are disposed adjacent to each other and are stacked in this order. A magnetization direction of either of the lower layer and the upper layer is fixed relative to an external magnetic field, and a magnetization direction of the other layer is variable in accordance with the external magnetic field. A crystalline portion and a non-crystalline portion co-exist in a plane that is parallel with a surface of the tunnel barrier layer.

Abstract: A magnetic field detecting element has a lower layer, a tunnel barrier layer, and an upper layer, wherein the lower layer, the tunnel barrier layer, and the upper layer are stacked adjacent to each other in this order, wherein a magnetization direction of either the lower layer or the upper layer is fixed relative to an external magnetic field, and a magnetization direction of the other can be changed in accordance with the external magnetic field such that a magnitude of the external magnetic field is detected based on a change in resistance relative to a sense current, the change in resistance depending on the external magnetic field, wherein the lower layer comprises: a first layer that is formed in an amorphous state; and a second layer that is made of cobalt, iron, nickel or a combination thereof and that is formed in a substantially amorphous state, the second layer being adjacent to the first layer and the tunnel barrier layer on both sides.