JPS63261503A - Magnetic head - Google Patents

Abstract

PURPOSE:To provide a magnetic reproducing head having high sensitivity by providing a magnetic path for guiding a magnetic flux for reproduction and a superconducting ring which constitutes a superconduction quantum interferometer crossing said path. CONSTITUTION:This head is constituted of the magnetic path 2 consisting of a magnetic alloy and an insulator 3 in common use as a magnetic gap on a substrate 1 consisting of a magnetic material such as Mn-Zn ferrite and is formed with a ring 4 constituted of a superconducting material so as to cross the magnetic path of the head. A Josephson junction 5 is formed to this ring and further a terminal part 6 is formed to constitute the superconduction quantum interferometer of a DC type. Detection of signals is executed by the superconduction quantum interferometer. The magnetic reproducing head having the extremely high sensitivity is thereby obtd.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a magnetic head, and more particularly to an ultra-high sensitivity reproducing magnetic head using superconducting quantum interference.

[Conventional technology]

High-density magnetic recording has made remarkable progress, and research into perpendicular magnetic recording, which is suitable for high-density magnetic recording, has progressed in recent years, and even in conventional longitudinal magnetic recording, improvements in magnetic heads and recording media have led to higher recording densities. There is.

When the linear recording density and track density are increased, the area of the recording medium provided per bit or per wavelength decreases, and thus the reproduction output decreases. It has been revealed that when recording is performed by perpendicular magnetic recording, signals with a maximum linear recording density of 500 KBPI can be recorded. However, when this recorded No. The present invention aims to solve the above problem and provide a reproducing magnetic head with extremely high sensitivity so as to be able to reproduce recorded signals with extremely high linear recording density and track density.

[Means for solving problems]

In order to solve the above problems, in the magnetic head of the present invention,
It consists of at least a magnetic path for guiding reproduction magnetic flux and a superconducting ring that constitutes a superconducting quantum interferometer that is linked to this magnetic path. In other words, a superconducting quantum interferometer (5u
per conductingQuantum Int
(abbreviated as 5QUID)
Use. A superconducting quantum interferometer is a superconducting quantum interferometer that uses the phenomenon that the superconducting current flowing through a superconducting ring containing one or two Josephson junctions changes according to the amount of magnetic flux that passes through the ring, and can be used to measure the amount of magnetic flux with high sensitivity. )ll'l is an element that determines.

Since this superconducting quantum interferometer utilizes a superconducting state, it was necessary to construct the device with a superconducting material and to cool the entire device to an extremely low temperature to achieve the superconducting state.

However, research and development of superconducting materials has made remarkable progress in recent years, and materials that become superconducting at an angle of about 95 degrees have been discovered.

By using such a high-temperature superconducting material, it is possible to construct an ultra-sensitive reproducing magnetic head using a superconducting quantum interferometer.

[Effect]

The magnetic head of the present invention includes at least a magnetic path for guiding reproduction magnetic flux and a superconducting ring that constitutes a superconducting quantum interferometer that interlinks with the magnetic path. Furthermore, by providing a configuration that includes a cooling element that utilizes the Peltier effect, it is effective to efficiently cool the necessary portions and maintain a superconducting state. Furthermore, the structure is such that the part to be cooled is separated from the recording medium facing surface of the head to facilitate cooling.

Once a normal coil is provided that interlinks with the magnetic path for guiding the reproduction magnetic flux, another magnetic path is formed that interlinks with this coil, and the magnetic flux of this magnetic path interlinks with the superconducting quantum interferometer element. You may also do so. In addition, in the case of this configuration, it is also possible to link the magnetic flux through space between the coil that interlinks with the magnetic path for reproducing magnetic flux and the superconducting quantum interferometer element without forming another magnetic path. This is possible due to the high sensitivity of superconducting quantum interferometer elements.

In the magnetic head of the present invention, the shape of the magnetic path for guiding the reproducing magnetic flux may be a conventional ring shape.

Alternatively, it can be constructed with a thin main pole film like a single pole type head for perpendicular magnetic recording.

Conventional heads require a coil with a large number of turns in order to improve reproduction sensitivity, but with the configuration of the present invention, it is only necessary to form a single ring using a superconducting material.
The advantage is that the process is greatly simplified.

The superconducting quantum interferometer used in the present invention includes a DC type that includes two Josephson junction elements and an AC type that includes - Josephson junction elements.6 The DC type forms two Josephson junctions. Although it is disadvantageous in terms of process compared to an AC type including - Josephson junctions, it has the advantage of a simple circuit configuration. On the other hand, the AC type requires only one Josephson junction to be formed, which is advantageous in terms of process, but the circuit configuration is complicated. Any type can be used in the magnetic head of the present invention, and the advantages of each type can be selected and used.

This is because the a-conducting quantum interferometer used in the magnetic head of the present invention is extremely sensitive to external magnetic flux.

It has the problem of being vulnerable to leakage magnetic flux other than external signals and noise such as ffi magnetic waves.

In order to solve this problem, it is desirable to provide the magnetic head of the present invention with a shield. As this shielding material, it is most preferable to use a superconducting material as a conventional Ni-Fe alloy (because Vermaro has the effect of preventing magnetic flux from penetrating the shielding material.

Furthermore, in the magnetic head of the present invention, it is possible to further facilitate signal detection by providing a bias coil arranged so that the magnetic flux interlinks with the superconducting quantum interferometer element, and by passing an alternating current bias current through the bias coil. It is.

Examples of the superconducting material used in the magnetic head of the present invention include (SrxLaz-x)zCuO4 (x = 0,
05-0.1) or (Bat-xYx)3Cu2
A material having a composition such as 07(x-0,3) can be used. In particular, the latter is a preferable material because it becomes superconductive at a high temperature of 95°.

Further, in the magnetic head of the present invention, by providing a recording coil interlinked with the magnetic path of the magnetic head, it can be used as a recording head in the conventional manner. As this recording coil, the aforementioned bias coil or a high frequency coil for signal detection used in an AC superconducting quantum interferometer can be used by switching to a recording film. By using a superconducting material as the material for this coil, heat generation due to the recording current can be suppressed to a minimum, resulting in an excellent recording head.

〔Example〕

Next, the magnetic head of the present invention will be explained in detail using examples.

Figure 1 shows two Josephson junctions in a ring-type magnetic head.
This is an example of a combination of direct current superconducting quantum interferometers.

Figure 1 (a) is a plan view with the protective material of the head removed.
(B) shows a cross-sectional view of AA' in (A).

This head is composed of a substrate 1 made of a magnetic material such as Mn-Zn ferrite, a magnetic pole 2 made of a magnetic alloy, and an insulator 3 serving as a magnetic gap, which interlink with the magnetic path of six heads. A ring 4 made of a superconducting material is formed, a Josephson junction 5 is formed in this ring, and a terminal portion 6 is further formed to constitute a direct current type superconducting quantum interferometer. An insulating material 7 is filled between the magnetic pole and the ring. In order to make sliding contact with the recording medium at the recording medium facing surface 8, this head has a protected forest 9 joined thereto.

FIG. 2 is an example of a magnetic head combined with an AC superconducting quantum interferometer. In this embodiment, the superconducting ring 4 includes one Josephson junction 5, and further includes a high frequency coil 1 for signal detection that is magnetically coupled to the superconducting ring.
It has 0. In a reproducing magnetic head equipped with a superconducting quantum interferometer as described above, the magnetic poles are configured so that the reproducing magnetic flux penetrates the superconducting ring of the superconducting quantum interferometer. It has the feature of being able to detect magnetic flux with ultra-high sensitivity.

FIG. 3 is an example of a head that combines a single-pole magnetic head and a superconducting quantum interferometer. FIG. 3(a) shows a plan view of the head, and FIG. 3(b) shows a plan view of parts B to B' in (a).

11 is a substrate made of a superconducting material, on which an insulating material 1 is placed.
A thin main pole film 13 made of a magnetic alloy is formed on top of the magnetic head 2 to form a single pole type head. Further, a superconducting material 14 is formed to sandwich the superconducting material 14, and two Josephson junctions 15 are formed between the superconducting material 11 of the substrate and a DC superconducting electron interferometer.

16 on the surface facing the recording medium, and a small amount of magnetic flux flowing from the medium is guided to the main pole film 13 and connected to the substrate 11.

A signal is detected by a signal line 17 that passes through a superconducting ring made of superconducting material 14 and is connected to substrate 11 and superconducting material 14 . In this head, the superconducting material 14 forming part of the superconducting ring is placed a distance d from the surface facing the recording medium as shown in FIG. 3(A). This is because when d is set to zero, the surrounding magnetic flux other than the target signal on the recording medium does not flow into the superconducting ring, resulting in a decrease in resolution.

To prevent this, by setting the distance d to a finite value,
It is possible to detect only the magnetic flux flowing into the main magnetic pole film 13.
Resolution can be improved. Since this head makes sliding contact with the recording medium at the medium facing surface 16, it is desirable to provide a protective forest 18 to protect the main pole film 13, as shown in FIG. 3(C). In addition, °Figure 3 (c)
shows the AA' cross section of (A). Although a non-magnetic material may be used as the protected forest 18, if a high magnetic permeability material such as ferrite is used for Mn-Zn, it will serve as a return path for the magnetic flux that has flowed into the main pole film 13. surface
The advantage is increased efficiency. In this case, it is necessary to provide a non-magnetic material 19 between the main magnetic pole film 13 and the protected forest 18 to prevent a magnetic short circuit between the protected forest 18 and the main magnetic pole film 13 in the vicinity of the medium facing surface. Furthermore, by using a superconducting material as the protective material 18, a complete magnetic shield can be achieved. At this time, 19 needs to be an insulating material.

FIG. 4 shows an example in which the superconducting quantum interferometer of the magnetic head shown in FIG. is formed and the other junction is shorted. Further, a high frequency coil 20 is provided so that the magnetic flux is coupled to the superconducting ring via the main pole film, and thereby signals are detected.

FIG. 5 shows another example of the single-pole type magnetic head shown in FIG. No. 5 showing the BB' cross-sectional view of a)
The head shown in the figure is constructed so that the protected forest 18 shown in Fig. 3 (c) forms part of the superconducting ring of the superconducting quantum interferometer. 11 and form a Josephson junction 15. 21 is a non-magnetic material and serves to protect the main pole film.

FIG. 6 is an example of a head having a structure in which the superconducting quantum interferometer portion of the head shown in FIG. 1 is separated from the surface facing the recording medium. (a) is a plan view with the protective material removed, and (b) is a cross-sectional view taken along line A-A' in (a). The magnetic flux is passed through a magnetic path consisting of a substrate 1 made of a magnetic material and a magnetic pole 2,
The magnetic flux transmission coil coil mass interlinking with this first converts it into a signal current, and then generates a magnetic flux in the rear magnetic path consisting of the rear substrate 23 and rear magnetic pole 24 that interlinks with this, and the superconductor that interlinks with this. The structure is such that a signal is detected by a ring 4 made of material. In this case, since the portion made of the superconducting material can be separated from the portion slidingly contacting the recording medium, it becomes easy to cool only the portion using the superconducting material. In the example of the head shown in FIG. 6, a cooling element 26 using the Peltier effect or the like is used in the part using a superconducting material via a material 25 with good superconductivity.
It becomes possible to efficiently cool the part using superconducting material. In such a case, it is desirable to separate the substrate forming the front magnetic path and the substrate forming the rear magnetic path using an insulating material 27 in order to thermally insulate them.

FIG. 7 omits the rear magnetic path of the head shown in FIG.
This is an example in which a coil that transmits a reproduction signal and a superconducting ring are magnetically coupled through space. Such a configuration is possible because the superconducting quantum interferometer has extremely high magnetic flux detection sensitivity.

Note that the head shown in Figures 6 and 7 shows only an example of a direct current type superconducting quantum interferometer, but as shown in Figure 2, a head that is combined with an alternating current type superconducting quantum interferometer may be used. Of course, it is also possible to do so.

FIG. 8 shows an example in which the magnetic path in the head shown in FIGS. 1, 2, 6, and 7 is made of only a magnetic alloy. That is, instead of the substrate 1 made of a magnetic material, a substrate 28 made of a non-magnetic material is used, and the lower magnetic pole 29 is provided on this substrate. In particular, in Figure 8 (b), the substrate on which the rear magnetic path and superconducting material are to be formed is cooled by a cooling element 3 using the Peltier effect.
By setting it to 0, it is possible to obtain a head that has even higher cooling efficiency and stably maintains a superconducting state.

FIG. 9 shows an example in which a magnetic shield is provided in the superconducting quantum interferometer portion of the head shown in FIG. Since superconducting quantum interferometers are extremely sensitive to magnetic flux, it is desirable to use a magnetic shield to prevent the generation of noise. Conventional high permeability materials can be used as the magnetic shield material, however. By providing magnetic shields 31 made of superconducting material above and below the magnetic poles shown in FIGS. 9(a) and 9(b), complete magnetic shielding is achieved. In this case, it is necessary to provide insulation between the magnetic pole and the magnetic pole by applying an insulating material 32 therebetween.

10 is an example in which a bias coil 33 is added to the superconducting quantum interferometer of the magnetic head shown in FIG. By using a head provided with such a bias coil, signal detection and signal processing in a superconducting quantum interferometer can be facilitated. Such a bias coil can be added to any of the heads shown in Fig. 1, Fig. 3, Fig. 5, Fig. 6, Fig. 7, Fig. 8, and Fig. 9 to obtain the same effect. There is.

Although the main purpose of the present invention is to provide a head with excellent reproduction characteristics, it is also possible to use a single head as a recording head in the same manner as in the past. On this occasion,
The superconducting ring for the superconducting quantum interferometer described so far may be used as a coil for applying recording current, but more preferably, the high-frequency coil 10 of the head shown in FIGS. 2 and 4,
20 and the bias coil 33 of the head shown in FIG. 10 may be used as a recording current applying coil during recording.

As the material for these recording coils, conventional Cu, Al, and alloys thereof may be used, but it is more preferable to use a superconducting material, so that even when a recording current of high current density is passed, This is more preferable because it can minimize the emission from the coil. Figures 3 and 6
The magnetic head as shown in FIGS. 7 and 7 is preferably provided with a recording current applying coil 34 as shown in FIG. 11.

In the embodiments of the present invention, the high frequency coil, bias coil, recording coil, magnetic flux transmission coil, etc. are all wound once, but may be wound multiple times, and better characteristics may be obtained in some cases.

〔Effect of the invention〕

As described above, the magnetic head of the present invention can reproduce weak signals with extremely high recording density with high sensitivity, is resistant to external noise, and generates little heat during recording.

[Brief explanation of the drawing]

It is a figure showing an example of. 1... Substrate, 2... Magnetic pole, 3... Insulating material, 4...
・Superconducting ring, 5... Josephson junction, 6...
Terminal portion, 7... Insulating material, 8... Recording medium facing surface, 9
...Protective material, 10...High frequency coil, 11...Substrate, 12...Insulating material, 13...Main pole film, 14...
・Superconducting material, 15...Josephson junction, 16...
Recording medium facing surface, 17... signal line. 18... Protective material, 19... Non-magnetic material, 20... High frequency coil, 21... Non-magnetic material, 22... Magnetic flux transmission coil, 23... Rear board, 24... Rear magnetic pole, 2
5... Heat conductive material, 26... Cooling element, 27...
Insulating material, 28... Substrate, 29... Lower magnetic pole, 30.
...Cooling element, 31...Magnetic shield, 32...Insulating material, 33...Bias coil, 34...Recording coil. 7th stitch, 2nd cut, 3rd stitch, 4th figure noya, 7th stitch 3z

Claims (1)

[Claims] 1. Consisting of a magnetic path for guiding magnetic flux and a ring made of a superconducting material containing a Josephson bond linked to this, signal detection is performed using a superconducting quantum produced by the ring. A magnetic head characterized by its operation using an interferometer. 2. The magnetic head according to claim 1, wherein the ring includes two Josephson couplings, and a DC type superconducting quantum interferometer is configured to detect signals. magnetic head. 3. The magnetic head according to claim 2, characterized in that a bias coil for facilitating signal detection is provided so as to be magnetically coupled to the ring made of the superconducting material. magnetic head. 4. The magnetic head according to claim 1, wherein the ring includes one Josephson coupling, includes a high-frequency coil for signal detection magnetically coupled to the ring, and includes an AC-type superconducting quantum A magnetic head comprising an interferometer to detect signals. 5. A magnetic head according to any one of claims 1 to 4, characterized in that the magnetic path for guiding magnetic flux is ring-shaped. 6. A magnetic head according to any one of claims 1 to 4, characterized in that the magnetic path for guiding magnetic flux is of a single magnetic pole type. 7. The magnetic head according to any one of claims 1 to 6, wherein a magnetic flux transmission coil interlinks with the magnetic path of the magnetic head, and a rear magnetic path interlinked with the magnetic flux transmission coil, and the rear magnetic head A magnetic head characterized in that a magnetic path and a ring made of the superconducting material interlink with each other. 8. In the magnetic head according to claim 7,
A magnetic head characterized in that the rear magnetic path is absent, and the magnetic flux transmission coil and the ring made of superconducting material are magnetically coupled through a space. 9. The magnetic head according to any one of claims 1 to 8, characterized in that the portion using the superconducting material is cooled by being combined with a cooling element using the Peltier effect or the like. magnetic head. 10. The magnetic head according to any one of claims 1 to 9, wherein a magnetic shield is provided around one or both of the magnetic pole part of the magnetic head or the ring made of the superconducting material. Features a magnetic head. 11. A magnetic head according to claim 10, characterized in that the magnetic shielding material is a superconducting material. 12. A magnetic head according to any one of claims 1 to 11, characterized in that a recording coil is provided that interlinks with a magnetic path of the magnetic head. 13. The magnetic head according to claim 12, wherein the recording coil also serves as the high frequency coil or the bias coil. 14. A magnetic head according to claim 12 or 13, wherein the recording coil is made of a superconducting material.