JPH10320768A - Master information carrier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To satisfactorily perform a batch surface recording by making a master information carrier substrate on which magnetic thin films are formed least on surfaces of projecting parts of a high polymer material, thereby realizing satisfactory contact states over the whole surfaces of the master information carrier substrate and a magnetic recording medium. SOLUTION: Projecting parts 2 and recessed parts 9 corresponding to master information pattern are formed on a substrate 7 consisting of high polymer material. Surfaces of the projecting parts 2 are composed of ferromagnetic material, and bottom surfaces of the recessed parts 9 are made to be either of the surface of the substrate 7 consisting of ferromagnetic material or high polymer material, or states in which the surfaces are recessed in the inside of the substrate 7. Then, the high polymer substrate 7 being flexible as compared with a hard disk substrate follows the inevitable deformation of the hard disk substrate made of the high polymer material and a pre-format recording to the hard disk medium is possible. High dimentional accuracy is required to the substrate consisting of the high polymer material and this accuracy is required in the pattern forming stage, the pre-format recording stage and the preservation stage of the master information.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a master information carrier provided with an information signal for recording an information signal on a magnetic recording medium of a magnetic recording / reproducing apparatus having a large capacity and a high recording density.

[0002]

2. Description of the Related Art In order to realize a small and large-capacity magnetic recording / reproducing apparatus, it is increasingly required to increase the recording density of a magnetic recording medium. A hard disk drive, which is a typical magnetic recording / reproducing apparatus, has an areal recording density of 1G.
A device exceeding bit / in ² (1.55 Mbit / mm ² ) has already been commercialized.
As the practical application of a device of 0 Gbit / in ² (15.5 Mbit / mm ² ) is predicted, rapid technical progress is recognized.

[0003] As a technical background enabling such a high recording density, there has been an emergence of a new signal processing method such as an improvement in medium performance, a head-disk interface performance, and a partial response. The improvement has greatly contributed to higher recording density. However, in recent years, the trend of increase in track density has greatly exceeded the trend of increase in linear recording density. This is due to the practical use of a magnetoresistive element type head, which has much better reproduction output performance than a conventional induction type magnetic head. At present, a few μm
A signal recorded with a track width of can be reproduced with a good SN ratio. With a further improvement in head performance, it is expected that the track pitch will reach the submicron range in the near future.

In order for the head to accurately scan such a narrow track and reproduce a signal with a good SN ratio, the tracking servo technique of the head plays an important role. Detailed information on such tracking servo technology is disclosed in, for example, Journal of the Japan Society of Applied Magnetics, Vol. 20, No. 3, p. 771 (1996), Yamaguchi, "High-precision Servo Technology for Magnetic Disk Drives". Have been. According to this document, in the current hard disk drive, one round of the disk, that is, 3
At an angle of 60 degrees, there are provided areas in which tracking servo signals, address information signals, reproduced clock signals, and the like are recorded at regular angular intervals. Recording such an information signal in advance is called preformat recording. By reproducing these signals at regular intervals, the magnetic head can check the position of the head, and can accurately scan the track while making corrections as necessary.

Since the above-mentioned tracking servo signal, address information signal, reproduction clock signal, and the like are reference signals for the head to accurately scan the track, it is required to have high head positioning accuracy in recording. . For example, the 93rd meeting of the Japan Society of Applied Magnetics, 93
-5, p. 35 (1996), Uematsu et al., "Mechanical Servo, HDI Technology Current Status and Prospects," According to the current hard disk drive, after the disk is built into the drive, Preformat recording is performed while strictly controlling the position of the magnetic head using a servo recording device.

[0006] Preformat recording by a magnetic head using such a dedicated servo recording device has the following problems. First, since recording by a magnetic head is basically linear recording by relative movement between the head and the medium, the above method of performing recording while strictly controlling the position of the magnetic head using a dedicated servo recording device is not used. In addition, a lot of time is required for preformat recording. Furthermore, dedicated servo recording devices are quite expensive. Therefore, the cost required for preformat recording increases.

This problem becomes more serious as the track density of the magnetic recording device increases. In addition to the increase in the number of tracks in the disk radial direction, the time required for preformat recording is prolonged for the following reasons. That is, the higher the track density, the higher the accuracy of the head positioning is required. Therefore, it is necessary to reduce the angular interval for providing a servo area for recording information signals such as a servo signal for tracking in one round of the disk. Therefore, the higher the recording density of the device, the larger the amount of signals to be preformat-recorded on the disc, and the more time is required.

[0008] Although magnetic disk media tend to be smaller in diameter, there is still a great demand for large-diameter disks of 3.5 inches or 5 inches. The larger the recording area of the disc, the larger the signal amount to be preformat-recorded. The time required for preformat recording also greatly affects the cost performance of such a large-diameter disk.

The second in conventional preformat recording
The problem is that the magnetic field spreads due to the spacing between the head and the medium and the shape of the pole at the tip of the recording head, so that the magnetization transition at the end of the preformat-recorded track lacks sharpness. .

Since recording by a magnetic head is basically dynamic line recording by relative movement between a head and a medium, a certain amount of head-medium spacing is provided from the viewpoint of the interface performance between the head and the medium. I have no choice. In addition, since the current magnetic head usually has a structure having two elements that separately perform recording and reproduction, the trailing edge pole width of the recording gap is equivalent to the recording track width, and the leading edge pole width is several times the recording track width. It is larger than above.

Both of the above two points cause a spread of the recording magnetic field at the end of the recording track, and as a result, the magnetization transition at the end of the track on which the preformat recording is performed lacks sharpness, or both sides of the track end. This results in the generation of an erased area in In the current tracking servo technology, the position of the head is detected based on the amount of change in the reproduction output when the head scans off the track. Therefore, not only is the S / N ratio excellent when the head scans the track accurately as in reproducing the data signal recorded between the servo areas, but also the reproduction output when the head scans off the track. It is required that the amount of change, that is, the off-track characteristic is steep. Accordingly, if the magnetization transition at the end of the track on which the preformat recording is performed lacks sharpness as described above, it is difficult to realize an accurate tracking servo technique in future submicron track recording.

Various techniques have already been proposed for solving the two problems in the preformat recording by the magnetic head as described above. For example, JP
Japanese Patent Application Laid-Open No. 3-183623 discloses a copying technique such as a tracking servo signal using a magnetic transfer technique as a solution to the first problem. It is a fact that the productivity at the time of preformat recording is improved by using this magnetic transfer technique. However, this magnetic transfer technology is effective for magnetic disk media having a relatively low coercive force and a low areal recording density, such as a flexible disk, but has a surface area on the order of several hundred megabits to a gigabit, such as today's hard disk media. It cannot be used for a high coercive force medium having a resolution that bears the recording density.

In the magnetic transfer technique, it is necessary to apply an AC bias magnetic field having an amplitude of about 1.5 times the coercive force of the transferred disk in order to secure transfer efficiency. Since the master information recorded on the master disk is a magnetization pattern, in order to prevent the master information from being demagnetized by the AC bias magnetic field, the coercive force of the master disk should be at least about three times the coercive force of the transferred disk. It is required that there be. The coercive force of the current high-density hard disk medium is 120 to 200 kA in order to support high areal recording density.
/ M. In order to support a surface recording density of 10 gigabit order in the future, this value should be 250 to 350 kA.
/ M is expected. That is, the coercive force of the master disk is required to be 360 to 600 kA / m at present, and 750 to 1050 kA / m in the future.

It is difficult to realize such a coercive force in the master disk from the viewpoint of selecting a magnetic material. Furthermore, with the current magnetic recording technology, master information cannot be recorded on a master disk having such a high coercive force. Therefore, in magnetic transfer technology,
Considering the coercive force value that can be realized in the master disk, the coercive force of the disk to be transferred is necessarily limited.

[0015] For example, in Japanese Patent Application Laid-Open No. Hei 7-153060, a disk medium substrate having an uneven shape corresponding to a tracking servo signal, an address information signal, a reproduction clock signal, and the like is formed by a stamper. A pre-embossed disk technology for forming a magnetic layer has been disclosed. This technique is an effective solution to both of the above two problems. However, it is expected that the uneven shape of the disk surface will affect the flying characteristics of the head during recording / reproduction (or the contact state with the medium in the case of contact recording), and as a result, a problem will occur in the head-medium interface performance. Is done. Also, since the substrate manufactured by the stamper is basically a plastic substrate,
There is also a problem that the substrate cannot be heated at the time of forming the magnetic layer necessary for securing the medium performance, and the required medium S / N ratio cannot be secured.

As described above, Japanese Patent Application Laid-Open No. 63-18362 discloses a solution to the above two problems relating to preformat recording.
The technique described in Japanese Patent Application Publication No. 3 or JP-A-7-153060 sacrifices other important performances such as a medium S / N ratio and interface performance, and is not a truly effective solution.

To solve such a problem, the productivity at the time of preformat recording is increased without sacrificing other important performances such as the medium S / N ratio and interface performance. The following method has been devised as a recording method for improving the steepness of the magnetization transition.

That is, according to the recording technique described in the specification of Japanese Patent Application No. 8-191889, an uneven shape corresponding to an information signal is formed on the surface of a substrate, and at least the surface of the convex portion of the uneven shape has a ferromagnetic property. The surface of the master information carrier made of a material is brought into contact with the surface of a sheet-shaped or disk-shaped magnetic recording medium on which a ferromagnetic thin film or a ferromagnetic powder coating layer is formed, so that the surface of the master information carrier is uneven. Is recorded on the magnetic recording medium.

As described above, in the preformat recording using the magnetic transfer technique, the surface of the master disk or the master information carrier and the surface of the magnetic recording medium need to be closely adhered over the entire area. One method for achieving this is disclosed in Japanese Patent Laid-Open No. 7-78337. In this method, the master medium and the slave medium (transfer medium) face each other, and the master medium and the slave medium are entirely pressed against each other by pressing means having an elastic body. At this time, if at least one of the master medium and the slave medium is a flexible medium, more reliable magnetic transfer is realized.

[0020]

However, in order to realize preformat recording at a surface recording density of 10 gigabit order which will be put to practical use in the future,
The technique for bringing the master information carrier and the magnetic recording medium into close contact with each other is not yet sufficient.

When the magnetic recording medium to be preformatted is a hard disk, the hard disk substrate is a high-strength rigid body such as metal, glass, silicon, or carbon. For example, it is desirable that the material be deformable to some extent, such as a polymer material.

When a polymer material which is more flexible than a hard disk substrate is used as a substrate (or base) of a master information carrier, various characteristics corresponding to a surface recording density of 10 gigabit order in the future and securing of handling are required. Significant improvement is needed. Specifically, the problem of expansion and contraction due to temperature and humidity fluctuations, the problem of thermal stability, dimensional stability, physical stability, and chemical stability in the production process of the master information carrier, and the problem of processability, It is necessary to solve the problem of dust adhesion due to static electricity during magnetic transfer.

[0023]

SUMMARY OF THE INVENTION In view of the above problems, the present invention provides a master information carrier capable of realizing preformat recording corresponding to a surface recording density of 10 gigabit order which will be put to practical use in the future. And has the following features.

A first feature is that in a master information carrier in which a concave / convex shape corresponding to an information signal is formed on a surface of a base and a magnetic thin film is formed on at least a convex surface of the convex / concave shape, the base is made of a polymer material. It consists of This allows the master information carrier to follow unavoidable deformation of a magnetic recording medium such as a hard disk substrate. As a result, a good contact state over the entire surface between the master information carrier and the magnetic recording medium is realized, and collective surface recording can be performed well.

Preferably, the base has a multilayer structure in which different types of polymer materials are laminated, so that thermal stability, dimensional stability, physical stability, chemical stability, which cannot be realized by a single material, Furthermore, workability can be ensured.

A second feature is that in a master information carrier in which an uneven shape corresponding to an information signal is formed on a surface of a base, and a magnetic thin film is formed on at least a surface of a convex portion of the uneven shape, the base is made of a metal, It is characterized in that it has a base material made of any one of an alloy and a ceramic material and a surface layer made of a polymer material formed on the surface of the base material. Thereby, the macroscopic shape stability of the master information carrier is improved, and the handling property of the master information carrier is improved.

Preferably, the base has a structure in which a film made of a polymer material is bonded to the surface of the base material. With such a structure, the master information carrier can be manufactured easily and at low cost.

Alternatively, the substrate has a surface layer made of a polymer material obtained by applying or casting a monomer or polymer precursor on the surface of the base material and then polymerizing the same. With such a structure, a master information carrier with high surface accuracy can be easily manufactured.

Alternatively, the base has a surface layer made of a polymer material formed on the surface of the base material by vacuum evaporation. With such a structure, a master information carrier with higher surface accuracy can be manufactured.

Further, it is preferable that the surface layer formed on the surface of the base material has a multilayer structure in which different kinds of polymer materials are laminated. This makes it possible to ensure thermal stability, dimensional stability, physical stability, chemical stability, and even processability that cannot be achieved with a single material. In addition, the macroscopic shape stability of the master information carrier is improved, and the handling of the master information carrier is improved.

In the first or second aspect, it is preferable that the substrate or the polymer material forming the surface of the substrate has an electric resistivity of such a degree as not to be charged. Thereby, adhesion of dust to the master information carrier is suppressed, so that good surface recording can be performed.

Similarly, in the first or second aspect,
It is preferable that fine particles containing a conductive substance as a main component are mixed and dispersed in the polymer material constituting the substrate or the substrate surface. With such a structure, it is possible to easily and inexpensively manufacture a master information carrier in which adhesion of dust is suppressed. It is particularly preferable that the conductive material contains carbon as a main component.

Further, in the first or second aspect, a conductive thin film is further formed on the surface of the base made of the polymer material, and an uneven shape corresponding to an information signal is formed on the conductive thin film. It is preferable that a magnetic thin film is formed on at least the surface of the projection. By adopting such a structure, it is possible to more reliably prevent static electricity and further suppress the adhesion of dust.

[0034]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, preformat recording using a master information carrier of the present invention will be briefly described. As shown in FIG. 1A, a recording magnetic field generated from a ferromagnetic material on a convex portion of the surface of the master information carrier magnetized in one direction causes a magnetization pattern corresponding to the concavo-convex shape of the master information carrier to be formed on the magnetic recording medium. Be recorded. That is, an uneven shape corresponding to a servo signal for tracking, an address information signal, a reproduction clock signal, and the like is formed on the surface of the master information carrier 1, and the ferromagnetic material of the convex portion is magnetized as shown by an arrow 4. Thereby, the magnetic recording medium 3 is magnetized as shown by the arrow 5. The residual magnetization corresponding to this is shown in FIG.
The magnetic recording medium 3 is preformat-recorded by remaining as shown by the arrow 6 in (b).

FIG. 2 is a sectional view showing an example of the uneven shape of the master information carrier according to the present invention. Base 7 made of polymer material
The convex portion 2 and the concave portion 9 corresponding to the master information pattern are formed thereon. The surface of the protrusion 2 is made of a ferromagnetic material 8. The bottom surface of the concave portion 9 is made of the ferromagnetic material 8 in the case of FIG. 2, but may be the surface of the base 7 made of a polymer material as shown in FIG. 3 or as shown in FIG. It may be depressed inside the base 7.

The thickness of the protruding portion of the ferromagnetic material 8 forming the surface of the protruding portion 2 varies depending on the bit length, the saturation magnetization of the magnetic recording medium, or the thickness of the magnetic layer. The saturation magnetization of the magnetic recording medium is about 500 emu /
cc, 50 nm to 500 nm for a film thickness of about 20 nm
It should be enough. The material of the ferromagnetic material 8 is not particularly limited as long as it can generate magnetization for recording on a magnetic recording medium.

The method for forming the ferromagnetic material 8 is not particularly limited, and ordinary vapor deposition, plating, sputtering and the like can be used. In addition, there is no particular limitation on the method for forming the uneven shape, and a lithography technique using a photosensitive resist agent, and further, a lift-off method, an ion milling method, a chemical etching method, or the like can be used.

A case where a lift-off method is used will be described as an example of a method for forming the uneven shape of the master information carrier. A photosensitive resist agent is applied to a thickness of about 1.5 μm on a polymer substrate by a spin coater. This is exposed and developed using a mask corresponding to the master information pattern,
A resist pattern is formed on a polymer substrate. Approximately 200n of Co film on polymer substrate with resist pattern
m. The conditions for forming the Co film are, for example, using a sputtering method and a sputtering gas pressure (Ar) of about 5 mTorr.
r, the film formation rate is about 50 nm / min.

After the Co film is formed, the resist and the Co film formed thereon are removed by ultrasonic cleaning in an organic solvent such as acetone. As a result, as shown in FIG. 3, only Co formed in the portion where no resist agent is present remains on the polymer substrate 7, and the remaining Co becomes the convex portion 2 of the master information carrier. The bottom surface of the concave portion 9 coincides with the surface of the polymer substrate 7, and the convex portion 2 made of the ferromagnetic material 8 is formed on the surface of the polymer material 7.

When the base is made of a polymer material, it is possible to preformat a hard disk medium having a magnetic layer formed on a rigid substrate. This is because the polymer substrate, which is more flexible than the hard disk substrate, follows the inevitable deformation of the hard disk substrate.

This polymer material substrate is required to have high dimensional accuracy. Moreover, this high dimensional accuracy must be realized in the master information pattern forming stage, preformat recording stage, and storage stage. At present, a polymer material having such performance does not exist as a single material. For example, polyimide-based and polyamide-based resins are materials having high thermal stability and chemical stability, but have a property of absorbing moisture and expanding. In addition, polyethylene terephthalate resin has a small water absorption expansion,
There is a problem with thermal stability. In addition, polypropylene-based and Teflon-based resins have problems such as difficulty in securing the adhesion of the film.

Therefore, by constructing the substrate in a multilayer structure in which different kinds of polymer materials are laminated, it is possible to make use of the characteristics of each material to complement each other's drawbacks.
It is possible to achieve the performance required for the base by overcoming the above problems.

Next, another example of the method for forming the uneven shape of the master information carrier of the present invention is shown in FIGS. 5 (a) to 5 (c). First, as shown in FIG. 5A, a polyimide solution (Trenice: manufactured by Toray) adjusted to a predetermined concentration with cyclohexanol is spin-coated on a glass base material 10 by a spin coater. At this time, the coating thickness is adjusted so that the thickness after curing becomes 1 μm.

Further, after curing this at a high temperature to form a polyimide layer 11, as shown in FIG. 5B, a Co film 12 is formed to a thickness of about 200 nm on the surface by sputtering.
The conditions for forming the Co film are as follows: a sputtering gas pressure (Ar) of about 5 mT.
orr, the film formation rate is about 50 nm / min.

Thereafter, a photoresist 13 is further formed on the surface.
Is spin-coated with a spin coater by 1 μm, exposed and developed using a mask corresponding to the master information pattern. Further, as shown in FIG.
After removing o with an ion milling device, the remaining photoresist is removed to obtain a master information carrier.

As another method, as shown in FIG. 6, irregularities are formed on the substrate 7 itself, and a layer 8 of a ferromagnetic material is formed thereon.
May be formed. In order to overcome the drawbacks of individual polymer materials, a plurality of polymer materials may be laminated to form a polymer substrate.

Further, by providing a polymer material on the surface of a base material using a metal, an alloy or a ceramic material to form a base, an effect of improving the thermal stability of the polymer material can be expected. In this case, it is difficult for the base material itself to sufficiently follow the deformation of the magnetic recording medium. However, if the polymer material on the surface of the base sufficiently follows the deformation of the magnetic recording medium and delicate undulation of the surface, the master information can be obtained. The magnetic thin film on each convex portion of the carrier surely follows the subtle undulation on the surface of the magnetic recording medium, thereby enabling sharp magnetic transfer.

As a method of forming the polymer material layer on the surface of the base material, (1) laminating a polymer film, (2) applying or casting a monomer or polymer precursor on the surface of the base material,
Further, methods such as subsequent polymerization and (3) formation of a polymer material on the base material surface by vacuum deposition can be used.
In forming this polymer material layer, a plurality of polymer materials can be laminated and used in order to complement the characteristics of each polymer material such as elasticity and chemical resistance.

Further, since the adhesion between the master information carrier and the magnetic recording medium is an important factor, the transfer process is desirably performed in an environment where dust is removed as much as possible. From the viewpoint of preventing dust from being attracted by static electricity, it is preferable that the polymer film formed on the surface of the base material contains a conductive material containing carbon as a main component to make it difficult to be charged. Alternatively, a metal film having a thickness that does not impair the elasticity of the polymer may be formed on the surface of the polymer film formed on the surface of the base material. metal,
When a polymer film is attached to the surface of a base material using an alloy or a ceramic material, a magnetic thin film may be formed between the polymer film and the base material.

[0050]

By using the master information carrier according to the present invention, a magnetic recording medium, in particular, a disk-shaped medium such as a fixed hard disk medium, a removable hard disk medium, and a large-capacity flexible medium can be efficiently used in a short time.
Moreover, preformat recording of a tracking servo signal, an address information signal, a reproduction clock signal, and the like can be stably performed. That is, according to the present invention, in the preformat recording on a magnetic recording medium having a surface recording density of the future gigabit order or more in the field of magnetic recording and reproducing apparatus, the adhesion between the master information carrier and the magnetic recording medium is improved, High-density preformat recording can be performed efficiently and stably.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing the principle of magnetic transfer to a magnetic recording medium by a master information carrier.

FIG. 2 is a cross-sectional view showing an example of an uneven shape of a master information carrier according to the present invention.

FIG. 3 is a cross-sectional view showing another example of the uneven shape of the master information carrier.

FIG. 4 is a sectional view showing another example of the uneven shape of the master information carrier.

FIG. 5 is a cross-sectional view showing an example of a process for forming an uneven shape on the surface of the master information carrier.

FIG. 6 is a cross-sectional view showing an example of a master information carrier in which a ferromagnetic material is formed on an uneven shape of a polymer substrate.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Master information carrier 2 Convex part 3 Magnetic recording medium 4 Magnetization direction of convex ferromagnetic material 5 Recording magnetic field 6 Residual magnetization direction of magnetic recording medium 7 Polymer substrate 8 Ferromagnetic material 9 Concave part 10 Glass base material 11 Polyimide film 12 Co Layer 13 Photoresist

Continued on the front page (72) Inventor Ryuji Sugita 6-9B202 Ayukawacho, Hitachi City, Ibaraki Pref. (72) Inventor Keizo Miyata 1006 Oazadoma, Kadoma City, Osaka Matsushita Electric Industrial Co., Ltd.

Claims (11)

[Claims] 1. A master information carrier having an uneven shape corresponding to an information signal formed on a surface of a base, and a magnetic thin film formed on at least a convex surface of the uneven shape, wherein the base is made of a polymer material. A master information carrier, characterized in that: 2. The master information carrier according to claim 1, wherein the base has a multilayer structure in which different types of polymer materials are laminated. 3. A master information carrier having an uneven shape corresponding to an information signal formed on a surface of a base, and a magnetic thin film formed on at least a surface of a convex portion of the uneven shape, wherein the base is made of a metal, an alloy, A master information carrier comprising: a base material made of any one of ceramic materials; and a surface layer made of a polymer material formed on a surface of the base material. 4. The master information carrier according to claim 3, wherein the base has a structure in which a film made of a polymer material is bonded to the surface of the base material. 5. The substrate according to claim 3, wherein the substrate has a surface layer made of a polymer material obtained by applying or casting a monomer or polymer precursor on the surface of the base material. Master information carrier. 6. The master information carrier according to claim 3, wherein the base has a surface layer made of a polymer material formed on the surface of the base material by vacuum evaporation. 7. A surface layer formed on a surface of the base material,
The master information carrier according to claim 3, wherein the master information carrier has a multilayer structure in which different kinds of polymer materials are laminated. 8. The master information carrier according to claim 1, wherein the base material or the polymer material constituting the base surface has an electric resistivity of such a degree as not to be charged. 9. The master information carrier according to claim 1, wherein fine particles containing a conductive substance as a main component are mixed and dispersed in the base material or the polymer material forming the base surface. 10. The master information carrier according to claim 9, wherein said conductive substance contains carbon as a main component. 11. A conductive thin film is further formed on the surface of the base made of the polymer material, and a concavo-convex shape corresponding to an information signal is formed on the conductive thin film, and a magnetic thin film is formed on at least a surface of the convex portion of the concavo-convex shape. 4. The master information carrier according to claim 1, wherein the master information carrier is formed.