TH6376B - Multilayer magnetic resistance probe - Google Patents

Abstract

Magnetic resistivity detectors combine multilayer measuring components constructed with one or more magnetic resistive components in a plane array. Each magnetic resistive component has a multilayer structure of at least two ferromagnetic layers. separated by a non-magnetic layer The non-magnetic layers are interconnected like antiferromagnetic. by connecting a static magnet at opposite ends of the ferromagnetic layer The bias layer separated from the magnetic resistivity measurement component is separated by a magnetic field. To bias the magnetic resistance measurement assembly at the point where there is no signal required for a linear response. Magnetic Resistivity Sensor It is formed by alternating layers of ferromagnetic compounds. and a layer of non-magnetic substances on the substrate and so on. The resulting structure was modeled using photolithographic techniques. to have a plane array of magnetic resistive components. Leads are applied to the array that fills the gaps that separate the resistive components to provide conductivity between the components in the plane of the structure.

Claims (9)

1.Multi-layer magnetic resistance probe It consists of the first and second layers of ferromagnetic material. Which are separated from each other by a layer of non-magnetic material. Resulting in a multi-layered magnetic structure Such a multi-layered magnetic structure is organized into a series of planes. Each member of the array is separated from its neighboring members by a space, a conductive layer is created on the array. Such conductive material is placed in the space between the members to provide a conductivity between them in the plane of the multilayer magnetic structure. Each of the aforementioned first and second pheromagnetic tiers of such members are antiferromagnetically linked by couplings. Magneto static at its opposite edge. Joint action field consisting of a magnetic coupling component And the exchange coupling that exists between the first and second pheromechanic layers of Each such member The field acts as a joint member between the first and second pheromagnetic classes. The magnetization of the first ferromagnetic layer was placed not parallel to the magnetization of the second ferromagnetic layer. The direction of magnetization in each ferromagnetic layer which rotates in response to the entered magnetic field. The resistance of a magnetic resistance detector is a function of the change in the angle between the directions of magnetization in the adjacent peromagnetic layer. 2. The detector according to claim 1, where the member Each member of that array has the desired shape. The largest dimension in the plane of the multilayer magnetic structure is less than 10.0 um. 3. The probe according to claim 2 where each member has a generally circular shape. Measure according to claim 2, where each member is generally shaped as a rectangle 5. The detector according to claim 1, where the aforementioned multilayer magnetic structure is arranged in a non-connected sequence. They are connected perpendicular to the pheromagnetic layer and capture the magnetic anisotropy in each of those pheromagnetic layers. 6. The detector according to claim 5, where the magnetic structure The multiple layers are arranged to form an array of openings through the aforementioned magnetic structure 7. The detector according to claim 6, where the array of openings forms an array of holes with the characteristic Typical circularly through the aforementioned multilayered magnetic structure 8. Detectors according to claim 5, where such a multilayer magnetic structure is fixed to at least one band of modulated width 9. Measure according to claim 8, where the bar is wider Of which is modulated It consists of an array of circular members that are joined together with 1 0. A measure of claim 1 where each member of the array consists of a circular member with the highest diameter. It is 10.0 um. 1 1. A measure according to claim 1 where each member of the said array has a rectangular shape. Which has the largest dimension, less than 10 um. 1 2. The probe according to claim 1, where the ferromagnetic material consists of materials selected from the group consisting of iron, cobalt, nickel-iron and Ferromagnetic alloys based on iron, cobalt, nickel or nickel-iron 1 3. Detectors according to claim 12 where such ferromagnetic materials contain nickel-iron. 1 4. Detectors according to claim 1, where the non-magnetic layer Consists of conductive material F 1 5. Measuring instruments according to claim 14 where such conductive material is a material chosen from the group consisting of silver, gold, red and ruthenium and conductive alloys of silver, gold, copper and ruthenium 1 6. The probe according to claim 15 where the aforementioned conductive material is silver 1 7. The meter according to claim 15 where the aforementioned conductive material is copper 1 8. The probe according to claim 1 Where the conductive layer consists of a non-magnetic conductive material. It is selected from a group consisting of chromium, tantalum, silver, gold, copper, aluminum and ruthenium. 1 9. Detectors in accordance with claim 18 by such non-magnetic conductive material. Contains chromium 2 0. Multilayer magnetic resistance probe. It consists of an N double layer, where each double layer consists of a layer of a ferromagnetic material built on a layer of non-magnetic material. The N double layers are built on the base layer of such ferromagnetic material. This creates a multi-layered magnetic structure, an alternating layer of ferromagnetic and non-magnetic materials. The top and base layers are ferromagnetic materials. Each pheromagnetic layer is linked in an antipherochemical way to its adjacent ferromagnetic layer by coupling a magneto-static at its corresponding edges. A co-acting field consisting of sub-components of a magnetic coupling. And the exchange coupling that exists between the adjacent ferromagnetic layers. The field acts in conjunction between the ferromagnetic layers that are adjacent to it as an antiferromagnetic. The magnetization in the ferromagnetic layer is arranged so that it is not parallel to the magnetization in the Fe layer. Romanotics next to each other The direction of magnetization in each ferromagnetic layer that rotates in response to the fed magnetic field. The resistance of a magnetic resistance detector is a function of the change in the angle between the directions of magnetization in the adjacent ferromagnetic layer 2 1. The detector according to claim 20 with additional components. It is a shield that is formed on the upper layer of such a multilayer magnetic structure. 2. 2. Measuring instrument according to claim 21, where the cover consists of a high-resistance non-magnetic material selected from a group containing tantalum silicon. Dioxide and Aluminum Oxide 2. 3. Detectors in accordance with claim 21 where the aforementioned multi-layer magnetic structure is bobbin to form a multi-plane array. Each member of an array is separated from its neighboring members by a space. Each member of the array has the same layer structure as the multilayer magnetic structure. A conductive layer of conductive material is created on such an array. Such conductive material is contained in the space between the members. 2 4. The detector according to claim 23, provided that such members of the array are of the desired shape with the dimensions of claim 23, the conductivity between them in the plane of the multilayer magnetic structure. The largest in the plane of such a multilayered magnetic structure is less than 10 um. 2 5. The meter according to claim 24 where each member is It consists of a circular member with a maximum diameter of 10.0 um. 2 6. Measuring probe according to claim 24 where each member is shaped in the form of a rectangle. Right 20 whereby the multilayer magnetic structure Was arranged in a non-continuous sequence, perpendicular to the pheromagnetic layer And intercept magnetic anisotypes in each of the aforementioned pheromagnetic layer 2. 8. Detectors according to claim 27 where the multi-layer magnetic structure The bobbin is arranged in an array of openings through the aforementioned multi-magnetic structure. 2 9. The detector in claim 28, where the array of openings forms an array of holes that are circular through the structure. Such multilayered magnet 3 0. Detectors according to claim 27, where such a multilayer magnetic structure is set up to be at least one strip modulated width. Clause 30 where the modulated width band is composed of an array of circular members connected together 3 2. Measuring instrument according to claim 21 where the ferromagnetic material is It consists of materials chosen from the group consisting of cobalt nickel-nickel-iron magnets and ferromagnetic alloys. Which is based on iron, cobalt, nickel or nickel - iron 3 3. Measuring instrument according to claim 32, where the ferromagnetic material is composed of nickel - iron 3 4. Measuring According to claim 21, where such non-magnetic material is composed of a conductive material 3 5. Measuring instrument according to claim 34 where such conductive material is a material chosen from the group consisting of silver, gold, copper and ruthenium. And conductor alloy of silver, gold, copper or ruthenium 3 6. Measuring instrument according to claim 35, where the said conductive material is silver 3 7. the meter according to claim 35 where the conductor material is copper 3 8. Transducer according to claim 23 where the conductivity layer contains non-magnetic conductive material. It is selected from a group consisting of chrome, tantalum, silver, gold, copper, aluminum and ruthenium and its conductive alloys of chromium, tantalum, silver, gold, copper, aluminum and ruthenium. It contains chromium 4.0. The probe according to claim 38, where the non-magnetic conductive material contains tantalum 4 1.The probe according to claim 21, where N is selected from the range 2 to 1C 4. 2. The detector is determined according to claim 21, where the sum of the thickness of the odd-numbered fedromagnetic layer is equal to the sum of the thickness of the even-numbered ferromagnetic layer 4. The detector according to claim 42, where the thickness of the aforementioned upper and base layers of the ferromagnetic material is half that of the ferromagnetic layer within the multilayer magnetic structure. Multilayer magnetic resistance, consisting of: base layer; The isolation layer applied to the main surface of the base layer; Bias layer of magnetic material deposited on such separation layer; Antimagnetic measuring component applied to the bias layer. And which consist of N pairs, where each double layer consists of a layer of ferromagnetic material. These pairs on the base layer of the ferromagnetic material are Resulting in a multi-layered magnetic structure Of alternating layers of ferromagnetic and non-magnetic materials The top and base layers are ferromagnetic materials, each pheromagnetic layer is linked in antipheromagnetic to the adjacent ferromagnetic layer. By coupling the magneto static at the corresponding edges of it A co-actuation field consisting of a sub-component of a magnetostatic coupling and an exchange coupling that appears between the adjacent ferromagnetic layers. The field acts in conjunction between the ferromagnetic layers that are adjacent to it as an antiferromagnetic. The magnetization in the ferromagnetic layer is arranged so that it is not parallel to the magnetization in the adjacent ferromagnetic layer. The direction of magnetization in each ferromagnetic layer that rotates in response to the fed magnetic field. The resistance of a magnetic resistance detector is a function of changing the angle between the directions of magnetization in the ferromagnetic layer. Next to each other Such a multi-layered magnetic structure is organized into a series of planes. Where each member of that array is separated from the neighboring members by the space Each member of the array has a base structure that is identical to the multilayer magnetic structure. The conductive layer of conductive material is placed on the above array. The conductive material is contained in the free space between the members. To provide electrical conductivity between such members in the plane of such multilayer magnetic structure The cover is made on the upper layer of the multilayer magnetic structure, and the insertion layer of non-magnetic material is deposited on the bias layer and placed between the bias layers. With such a magnetic resistance measuring component To disconnect magnetically the bias layer from the aforementioned magnetic resistance measuring factor 4 5. The detector according to claim 44 where the number of N of even layers is selected from the range 1 to 10 4 6. The probe according to claim 44 where each component consists of a circular component with a maximum diameter of 10.0 um. 4 7. The probe according to claim 44 where each component It consists of a rectangular component with a maximum dimension of less than 10 um. 4 8. Measuring probe according to claim 44, the aforementioned ferromagnetic material consists of materials selected from the group consisting of cobalt steel. Nickel nickel - iron and ferromagnetic alloys Which is based on iron, cobalt, nickel, or nickel - iron 4 9. Measuring instrument according to claim 48, where the ferromagnetic material is composed of nickel - iron 5 0. According to claim 44, where the non-magnetic layer Contains a selection of conductors from a group of silver, gold, copper and ruthenium. And conductive alloys of silver, gold, copper or ruthenium. 5 1. The detector according to claim 50 where the said conductive material is silver 5 2. the meter according to claim 44 where the insert layer consists of material that Select from a group consisting of tantalum, zirconium, titanium, yttrium, and hafnium. 5 3. Detectors according to claim 52, where the insert layer consists of the material selected from the group consisting of tantalum 5 4. the detector according to claim 44, where The bias class consists of a layer of magnetically soft material to induce such a magnetic bias field. 5 5. Detectors according to claim 54, where such magnetic soft material is composed of a selected material from a group consisting of: Nickel-Iron And Nickel-Iron-Rhodium 5 6. Detectors according to claim 44, where the bias layer consists of a layer of magnetic hardened material for the aforementioned magnetic bias field. Measured according to claim 56, the magnetic solid material is composed of selected materials from the Cobalt-Platinum group. And cobalt-platinum, chromium 5. 8. The meter according to claim 44, with the aforementioned ferromagnetic layer thickness within the range of approximately 10 angstroms to approximately 100 angstroms. Claim 44 where the non-magnetic layer has a thickness within the range of approximately 10 angstroms to approximately 400 angstroms 6 0. Determination according to claim 44 where the aforementioned class consists of a conductive material that Non-magnetic, selected from a group consisting of chromium, tantalum, silver, gold, copper, aluminum and ruthenium, and an alloy of chromium, tantalum, silver, gold, copper, aluminum, and ruthenium 6 1. It consists of 6 tantalum 2. The meter is made according to claim 44, where the sum of the thickness of the odd number of ferromagnetic layers. It is equal to the sum of the thickness of the even-numbered ferromagnetic layers within the multilayer magnetic structure. 6 3. Magnetic storage system. Which includes: a magnetic storage medium with a group of tracks established on that surface for recording data. Magnetic transducers, which are closely separated from the said magnetic storage medium, during the relative motion between the transducer and the magnetic storage medium. The magnetic transducer consists of a multi-layer magnetic resistance detector. Which consists of a magnetic resistance measuring component Which consists of groups of N pairs, where each double layer consists of a Of ferromagnetic material These pairs on the base layer of the ferromagnetic material are Causing a multi-layered magnetic structure Of alternating layers of ferromagnetic and non-magnetic materials, the top and base layers are ferromagnetic. Each of the pheromagnetic layers are linked in an antipheronic way to the adjacent pheromagnetic layers. By coupling the magneto static on the opposite edge. A co-acting field consisting of sub-components of such magneto-static coupling. And the exchange couplings that appear between the adjacent ferromagnetic layers The field acts in conjunction between the ferromagnetic layers that are adjacent to it as an antiferromagnetic. The magnetization in the ferromagnetic layer is arranged so that it is not parallel to the magnetization in the adjacent ferromagnetic layer. The direction of magnetization in each ferromagnetic layer that rotates in response to the fed magnetic field. The resistance of a magnetic resistance detector is a function of changing the angle between the directions of magnetization in the adjacent ferromagnetic layer. Such a multi-layered magnetic structure is organized into a series of planes. Where each member of the hierarchy is separated from the adjacent members by space that each member of the hierarchy has the same layered structure as the multilayer magnetic structure. The conductive layer of conductive material is placed on the above array. The conductive material is contained in the free space between the members. To provide electrical conductivity between such members in the plane of such multilayer magnetic structure Bias layer of magnetic material for producing a magnetic bias field for such a resistive-magnetic sensing component. The insertion layer of a non-magnetic material is placed between the bias layer and the base layer of the aforementioned resistive-magnetic sensing component that disengages the magnetic linkage of the bias layer from the Such resistance measurement components and the conductors connected to the The opposite ends of the magnetic resistance sensor, respectively, to connect the multilayer magnetic resistor to the external circuit. And for linking the measuring current with the inspection components Measure such magnetic resistance A propulsion device that is linked with such a magnetic transducer to move the transducer. (Such magnet Choose to insert data on that magnetic storage medium and) a detector that is linked to the detector. Such multi-layer magnetic resistance To minimize resistance changes in the aforementioned magnetic resistance measuring component in response to the fed magnetic field. Which represent bits of information 6 4. Magnetic storage system according to claim 63 where the number of N pairs is selected from the range 1 to 10 6. 5. Magnetic storage system according to claim 63, where such components It consists of circular components with a maximum diameter of 10.0 um. 6 6. Magnetic storage system according to claim 63, where each component It consists of rectangular components with a maximum dimension of less than 10 um. 6 7. Magnetic storage system according to claim 63, where such ferromagnetic materials are composed of selected materials from the group consisting of cobalt steel. Nickel nickel - iron and ferromagnetic alloys Which is based on iron, cobalt, nickel or nickel-iron 6 8. Magnetic storage system according to claim 63, where the ferromagnetic material is composed of selected materials from the group consisting of cobalt-ni iron. Nickel-iron and ferromagnetic alloys based on iron, cobalt, nickel or nickel-iron 6 9. Magnetic storage system according to claim 68 where the ferromagnetic materials are as follows. It consists of a nickel-iron 7 0. Magnetic storage system according to claim 63, where the non-magnetic layer consists of a selected conductive material from a group consisting of silver, gold, copper and ruthenium. And conductive alloy of silver, gold, copper or ruthenium. 7 1. Magnetic storage system in accordance with claim 70 where the said conductive material is silver 7 2. Magnetic storage system according to claim 63 where the insertion layer consists of Materials selected from the group consisting of tantalum, zirconium, titanium, yttrium and hafnium. 7 3. Magnetic storage system according to claim 63, where the bias layer consists of a layer of magnetically soft material for the magnetic bias. Such magnetically weak materials Choose from a group consisting of nickel-iron-chromium. Nickel-Iron-Niobium Nickel-Iron and Nickel-Iron-Rhodium 7 4. Magnetic storage system according to claim 63 where such bias layer contains magnetic hard materials for making Such a magnetic bias field occurs. The magnetic material was selected from a group consisting of cobalt-platinum. And cobalt-platinum, chromium 7 5. Magnetic storage system according to claim 63, where the pheromagnetic layer has a thickness within the range of approximately 10 angstroms to approximately 100 angstroms. Magnetism according to claim 63, where the non-magnetic layer has a thickness within the range of approximately 10 angstroms to approximately 400 angstroms 7 7. Magnetic storage system according to claim 63 where the aforementioned layer consists of materials. Non-magnetic conductors selected from a group consisting of chromium, tantalum, silver, gold, copper, aluminum and ruthenium, and alloy conductors of chromium, tantalum, silver, gold, copper, aluminum and ruthenium. Magnetic resistance measurement The multi-layered resistive structure consists of an array of resistive-magnetic components. Each of these resistive components has a group of ferromagnetic layers. Each of these phoromagnetic layers is separated by an insert layer of a non-magnetic material. Each of these resistive components in that array is separated from the neighboring resistive components by free space. A layer of conductive material made on and between such resistive components. Such conductive material is contained in the free space between the resist-magnetic components. The method consists of steps of Making a base layer of a ferromagnetic material on a substrate. Each of these pairs consists of a first layer of non-magnetic material and a second layer of said ferromagnetic material. It was made on the first such layer. The double layer group was made on the said base layer of the aforementioned ferromagnetic material. Shuttle arrangement The resulting multi-layered magnetic structure that forms a multiple plane array. Each member of the array is separated from its neighboring members by free space. Each member of the array has the same layer structure as the multilayer magnetic structure and conducts a conductive layer on the array. The conductive material contains the space between the members to create conductivity. Electricity between the members in the plane of a multilayer magnetic structure 7 9. Method according to claim 78, where such a ferromagnetic layer has a thickness within the range of approximately 10 angstorm to approximately 100. Angstrom 8 0. The method according to claim 78, where the non-magnetic layer has a thickness within the range of approximately 10 angstroms to approximately 400 angstroms 8. 1. Multi-layer magnetic resistance measuring plate consisting of a substrate; The separator layer which forms on the main surface of the base plate. A bias layer of magnetic material that is covered on the separating layer. Magnetic resistance measuring components Which is encrusted on the aforementioned bias layer and consists of a group of N double layers, where each double layer consists of a pheromagnetic layer made on a layer of N non-magnetic material. On the base layer of the said ferromagnetic material This creates a multi-layered magnetic structure of alternating layers of ferromagnetic and non-magnetic materials. The top and base layers are ferromagnetic materials.Each ferromagnetic layer is antipheromagnetically linked to the adjacent ferromagnetic layer by coupling magnetism. Stable at opposite edges The co-acting field, which includes the sub-components of such anti-magnetic coupling And the exchange couplings that appear between the adjacent ferromagnetic layers The field acts in conjunction between the ferromagnetic layers that are adjacent to it as an antiferromagnetic. The magnetization of the ferromagnetic layer is placed so that it does not parallel to the magnetization of the adjacent ferromagnetic layer. The direction of magnetization in each rotating fade-magnetic layer responds to the magnetic field fed to it. Magnetic resistance probe resistance It is a function of changing the angle between the directions of magnetization in the adjacent ferromagnetic layer. The multi-layered magnetic structure is bobbin to form a single resistive component, the magnetic resistance component has the same dimensions as the required track width. The covering layer is made on the upper layer of the multilayer magnetic structure and the insertion layer of non-magnetic material which is deposited on the bias layer and placed between the bias layers. And the aforementioned magnetic resistance measurement components To disconnect the bias layer from the resistance measurement component 8 2. Detectors according to claim 81 where the number of N of even layers is selected from the range 1 to 10 8. 3. Detectors according to claim 81 where such ferromagnetic materials are composed of materials selected from the group consisting of iron, cobalt, nickel-iron and ferromagnetic alloys. Which has the basis of iron, cobalt, nickel or nickel-iron 8 4. Detectors according to claim 81, where such non-magnetic layer consists of a conductive material selected from the group consisting of silver, gold, copper and ruthenium and conductive alloys of silver, gold, copper or ruthenium 8. 5. Detectors in accordance with claim 81, where the insert layer consists of materials selected from a group consisting of tantalum, zirconium, titanium, yttrium and hafnium 8. 6. Detectors according to claim 81, where such a bias layer consists of a layer of soft magnetic material to provide such a magnetic bias field. Such magnetic soft materials are selected from a group that includes: Nickel-Iron-Chromium Nickel-Iron-Niobium Nickel-Iron and Nickel-Iron-Rhodium 8 7. Detectors according to claim 81, where such a bias layer contains a layer of soft magnetic material for the formation of such a magnetic bias field. The magnetic solid material was selected from a group consisting of cobalt-platinum. And cobalt-latinum-chromium 8 8.The detector is in accordance with claim 81, with the aforementioned ferromagnetic layer thickness within the range of approximately 10 angstroms to approximately 100 angstroms 8. 9.The detector according to claim 81, where the non-magnetic layer has a thickness within the range of approximately 10 angstoms to approximately 400 angstroms.