KR100383564B1 - Method for forming impedance-valve type material and impedance-valve type material fabricated using the same - Google Patents

Abstract

The present invention relates to a method for forming an impedance valve type material and an impedance valve type material thereof. A method of forming an impedance valve type material includes a ferromagnetic layer formed on a surface of a magnetic material by heat-treating a magnetic thin film made of a soft magnetic material, an amorphous magnetic ribbon, a fine magnetic wire, and a magnetic crystal material. giant magneto impedance (GMI) GMI shows no magnetic hysteresis at low magnetic fields compared to giant magneto resistance (GMR), and its magnetic sensitivity is more than 100 times higher than that of GMR. Can be used as

Description

Method for forming impedance valve type material and its impedance valve type material {Method for forming impedance-valve type material and impedance-valve type material fabricated using the same}

The present invention relates to a method for forming an impedance valve type material and an impedance valve type material made therefrom.

Since data storage technology using magnetic disks was first developed in the late 70's with a read head using magnetic resistance (hereinafter referred to as MR), in the late 90's, more than a few gigabytes per square inch High-density magnetic recording media and readheads for recording and reproducing are under research and development.

In the advancement of memory-related products, device development plays a more important role than development of recording media, and high-density magnetic recording media using MR phenomenon and heads for recording / reproducing data from the media have been developed and used in some high-end products. . As shown in FIG. 1, the magnetic head has a step-shaped magnetoresistance of about several percent in the operating magnetic field by exchange coupling between the magnetic layers of the multilayer magnetic thin film, and thus the spin-valve type having excellent magnetic field sensitivity. -valve type) A material exhibiting a giant magnetoresistance (Giant MR) phenomenon is being applied to a magnetic head. In addition, since magnetic field resolution is superior to that of a Hall effect device as shown in FIG. 5, MR is being used for various magnetic sensors.

The magnetic head using the spin-valve type GMR material according to the prior art is formed by stacking two or more layers of a ferromagnetic layer, a quasi-ferromagnetic layer, and an anti-ferromagnetic layer. Smooth recording and reproducing of high frequency magnetism are difficult, and use as a medical magnetic sensor used to measure finer magnetism is more difficult.

In order to solve the above problems, the present invention provides a material formation method exhibiting an impedance valve type GMI (Giant magneto-impedance) characteristic that can be used for a fine magnetic head or a magnetic sensor, and an impedance manufactured using the same. To provide a valve-type GMI material.

Another technical problem to be solved by the present invention is to increase the magnetic sensitivity and the magnetic resistance, and to form a GMI material exhibiting an impedance valve phenomenon that can be utilized as a magnetic head and a magnetic field detection sensor of a highly sensitive information recording medium. To provide a manufactured impedance valve type GMI material.

1 is a GMR graph according to the magnetic field change of the GMR material.

2 is a GMI graph according to the magnetic field change of a typical GMI material.

3 is a GMI graph according to the magnetic field change of the GMI material according to the present invention.

4A to 4C are basic models of a magnetic head using impedance valve type GMI characteristics.

5 is a graph illustrating magnetic field sensitivity of various magnetic sensors.

FIG. 6 is a circuit diagram illustrating a multivibrator type MI impedance sensor using a material representing an impedance valve phenomenon.

FIG. 7 is a circuit diagram illustrating a differential magnetic impedance sensor (differential type MI sensor) using a material representing an impedance valve phenomenon.

<Explanation of symbols for the main parts of the drawings>

10, 20, 30 ... GMI valve, a, d ... terminal for current application

b, c ... Impedance measuring terminal, H _ext ... Applied magnetic field

In the GMI material forming method according to the present invention for achieving the above technical problem, by forming a ferromagnetic layer on the surface by heat treatment in the air applied to the magnetic material in the magnetic material by the bonding force between the magnetic material layer and the ferromagnetic layer Impedance valve type GMI effect.

The sample used in the present invention used a high permeability Co-based amorphous magnetic ribbon (Co ₆₆ Fe ₄ NiB ₁₄ Si ₁₅ ) and Invar wire (Fe ₆₄ Ni ₃₆ , 1μm), but the material exhibiting impedance valve phenomenon This is not limited only. In a preferred embodiment of the present invention, a magnetic field was applied from the outside in the axial direction (length direction) of the magnetic material or in a direction perpendicular to the axis while performing heat treatment at about 380 ^° C. for about 1 hour to 8 hours. In this embodiment, the best properties were when the applied magnetic field was about 2 Oe. In this heat treatment, a permanent magnetic layer is formed in the direction of the external magnetic field by crystallization or crystallization on the surface of the magnetic body. The present invention provides a method for forming a material in which the magnetic layer exhibits an impedance valve phenomenon in which the magnetic field sensitivity is greatly improved by a magnetic field, and an impedance valve type GMI material manufactured using the same.

Hereinafter, a material showing an impedance valve type GMI phenomenon according to the present invention and an application technology using the same will be described in detail with reference to the accompanying drawings.

1 is a GMR graph according to the change in the magnetic field of the GMR material. 1 shows a spin valve type MR phenomenon used for a high density magnetic recording medium and a head for recording and reproducing. As shown in the figure, a sudden resistance change such as a step occurs near a "0" magnetic field and is used in a conventional magnetic sensor.

2 is a graph illustrating the GMI effect according to the change of the magnetic field of a general GMI material. The GMI shown in the ferromagnetic film, which is a high permeability magnetic material, has a change in magnetic field of about 100% compared to that of a conventional GMR. Although it is known that the effect is 50 times or more and the magnetic sensitivity (% / Oe) is about 100 times, it shows the pyramidal GMI effect as shown in FIG. 2 and is not suitable as a magnetic sensor for measuring the strength of the fine magnetic field. There is this.

3 is a magnetic field vs. impedance change rate graph of an impedance valve type GMI material according to the present invention, in which the magnetic sensitivity in the operating magnetic field is about 1000 times that of GMR. The impedance valve type GMI phenomenon is characterized in that when a ferromagnetic layer is formed on the surface of a magnetic material by heating a magnetic material such as a magnetic thin film, an amorphous magnetic ribbon, a fine magnetic wire, and a magnetic crystal in an air or inert gas atmosphere, The magnetic force has the impedance valve type GMI characteristics as shown in FIG. Such a material having a GMI effect can be used for the magnetic head and various magnetic sensors of the information recording medium.

4A to 4C are basic model diagrams schematically showing a magnetic head for recording and reproduction using a magnetic material exhibiting impedance valve type GMI characteristics. 4a to 4c, H _ext represents a magnetic field, a and d are terminals for applying current, and b and c are voltage measurement terminals for impedance measurement. Impedance is measured using the Ohm's law Z (Ω) = V / I by reading the change of voltage V according to the applied current I. 4A to 4C, when the magnetic tape or the magnetic recording medium is excessively used on the material having the impedance valve type GMI characteristic, a small magnetic field change is generated, and the impedance of the material having a large magnetic sensitivity to the small magnetic field change is large. By making a change and measuring the change, it is possible to read the record of the recording medium. In this case, the impedance change shows a magnetic sensitivity about 1000 times larger than the magnetic head using the conventional spin-valve type GMR material, so that the quality of recording and reproduction can be improved and the recording density can be increased. -It can solve the problem of magnetic head using valve type GMR material.

FIG. 6 is a circuit diagram illustrating a multivibrator type MI impedance sensor using a material representing an impedance valve phenomenon. FIG. 7 is a circuit diagram illustrating a differential magnetic impedance sensor (differential type MI sensor) using a material representing an impedance valve phenomenon.

At present, two types of magnetic sensors using the GMI-type magnetic material, that is, the multivibrator type and the differential type magnetic sensors, such as the circuits shown in FIGS. 6 and 7, have been developed and are in use at the laboratory level. In FIG. 6, the multivibrator-type voltage E and the magnetic field H _ext are applied to the valve 60, and the output V _out is amplified by the amplifier 65 by amplifying the result detected by the valve 60, which is a magnetic sensor. In FIG. 7, the differential voltage E and the magnetic field H _ext are applied to the valve 70, and the bias coil 72 is positioned at the rear of the valve sensor 70, thereby providing a magnetic sensor at the valve 70. The sensed result is amplified by the amplifier 75 and outputs the output V _out . In these cases the GMI material is not an impedance valve type material as in the present invention. That is, according to the experimental results, the GMI phenomenon is also exhibited in the microwire material having a diameter of 1 μm or less, and using an impedance valve type GMI material formed by heat-treating an amorphous magnetic wire having a diameter of 1 μm, the conventional reported GMI material (impedance) It has about 50 to 100 times better resolution than the 10 ^-5 Oe resolution of a local magnetic field sensor developed at the laboratory level (not with a valve-type GMI).

As described above, the GMI material forming method according to the present invention heat-treats a magnetic thin film made of a soft magnetic material, an amorphous magnetic ribbon, a fine magnetic wire and a magnetic crystal material to form a ferromagnetic layer on the surface of the magnetic material. Impedance valve type GMI characteristics, applied to the magnetic head, the same size as the currently developed ultra-compact MR head, the sensitivity can be improved by 1,000 times. And a local magnetic field sensor was developed at the laboratory level with 10 ^-5 Oe resolution in an amorphous magnetic material with a diameter of 1 μm using the general GMI effect (not an impedance valve type GMI). It can be improved by 50 to 100 times or more. In addition, the magnetic hysteresis is not exhibited in a low magnetic field compared to GMR, and the magnetic sensitivity is high, so that it can be easily used for wires or thin films having a diameter of 1 μm or less.

Claims (4)

A method of forming an impedance valve type giant magnetic impedance (GMI) material having a ferromagnetic layer on its surface, the method comprising: a magnetic thin film made of soft magnetic material, an amorphous magnetic ribbon, a fine magnetic wire, an invar, and a magnetic crystal material A method of forming a GMI material having an impedance valve type giant magnetic impedance (GMI) characteristic by forming a ferromagnetic layer on a surface of a magnetic material by subjecting a material selected from the group to magnetic field heat treatment in air or inert gas conditions. In an impedance valve type giant magnetic impedance (GMI) material having a ferromagnetic layer on its surface, a magnetic thin film of soft magnetic material applied to the surface, an amorphous magnetic ribbon, a fine magnetic wire, invar and a magnetic crystal material And a material layer selected from the group, wherein the selected material layer has an impedance valve type giant magnetic impedance (GMI) characteristic formed of a ferromagnetic layer by magnetic field heat treatment in air or in an inert gas condition. delete delete