The present invention relates to a data rewritable magneto-optical recording medium and a method for producing the same.
An example of a data recording method for a magneto-optical recording medium is the magnetic field modulation method. When recording data using the magnetic field modulation method, a laser beam is irradiated onto the recording target section of the magneto-optical recording medium and the magnetic field corresponding to the data is applied. When using this method, the magneto-optical recording medium should preferably have a structure which enables the magnetic field to be used efficiently.
A magneto-optical recording medium having a soft magnetic layer is ideal for the magnetic field modulation method. Such a magneto-optical recording medium is described, for example, in Japanese Patent Application Laid-open No. H03-137837. The magneto-optical recording medium of this patent application has a structure wherein a soft magnetic layer, a light curing resin layer, a magneto-optical recording layer and a protective layer are laminated sequentially onto a substrate. The surface of the light curing resin layer has a convex-concave shape, where a plurality of grooves and a plurality of lands are provided alternately side by side.
In the conventional magneto-optical recording medium, a magnetic field generated by a magnetic head, which is positioned facing the protective layer, extends through the protective layer, the magneto-optical recording layer and the light curing resin layer. Then, the magnetic field is moved through the soft magnetic layer in a direction parallel to this layer, and is again passed through the light curing resin layer, the magneto-optical recording layer and the protective layer to return to the magnetic head. Moving the magnetic field around in such a closed loop enables the magnetic field to act efficiently on the recording target section, which is ideal for recording data.
However, in the above-mentioned conventional technology, the lands are located to either side of the grooves. When, for example, a laser beam is irradiated onto the grooves with the aim of writing data onto the same, the laser beam may also be irradiated onto the lands. On the other hand, the soft magnetic layer has the same thickness for both the grooves and lands, where the magnetic field applied to the grooves may also act efficiently on the lands. This at times results in cross-writing whereby data is mistakenly written onto the lands when writing data onto the grooves. This type of cross-writing particularly becomes more evident as the track pitch of the magneto-optical recording medium, which is designed to increase the data recording capacity, becomes smaller.
An object of the present invention is to provide a magneto-optical recording medium and a method for producing the same which is capable of solving or alleviating the above-mentioned problem.
The magneto-optical recording medium as provided by the first aspect of the present invention is a magneto-optical recording medium comprising a soft magnetic layer and a magneto-optical recording layer which are laminated sequentially onto a substrate, and the recording medium is provided with a plurality of grooves and a plurality of lands. The product of the saturation magnetic flux density and the thickness of the soft magnetic layer is different for each groove and each land.
The thickness of the soft magnetic layer may preferably be different for the respective grooves and lands.
The material of the soft magnetic layer may preferably be the same for each of the grooves and the lands.
Each of the grooves may preferably be a data recording target section, where the thickness of the soft magnetic layer for each of the grooves is greater than that for each of the lands.
Each of the lands may preferably be a data recording target section, where the thickness of the soft magnetic layer for each of the lands is greater than that for each of the grooves.
The method for manufacturing a magneto-optical recording medium as provided by the second aspect of the present invention comprises: a first step of manufacturing a substrate with a surface on which a plurality of pre-grooves are formed; a second step of forming a soft magnetic layer on the surface of the substrate; and a third step of forming a magneto-optical recording layer on the soft magnetic layer and providing a plurality of grooves and a plurality of lands. In the second step of the above method, a soft magnetic material film is formed on the surface of the substrate to a thickness greater than depths of the pre-grooves, and the soft magnetic material film is subjected to etching to be varied in thickness at sections corresponding to each groove and each land.
The formation of the soft magnetic material film may preferably be performed by sputtering and the etching process of the soft magnetic material film may preferably be performed by dry etching.
The manufacturing method of the magneto-optical recording medium as provided by the third aspect of the present invention comprises: a first step of forming a substrate; a second step of forming a soft magnetic layer on the substrate; and a third step of forming a magneto-optical recording layer on the soft magnetic layer for providing a plurality of grooves and a plurality of lands. In the method, a mold member having an indented-and-raised surface is used to form, on the surface of the mold member, a soft magnetic layer with a different thickness at the indented and the raised sections of the mold member, and then the soft magnetic layer is transcribed onto the substrate via a resin layer.
The soft magnetic layer may preferably be produced by forming, on the surface of the mold member, a soft magnetic material film having a thickness greater than the surface gap of the mold, and then the soft magnetic material film is subjected to etching.
The formation of the soft magnetic material film may preferably be performed by sputtering and the etching of the soft magnetic material film may preferably be performed by dry etching.
Easy release treatment may preferably be performed on the surface of the mold member prior to forming the soft magnetic material film on the surface of the mold member.
Other features and advantages of the present invention become clearer from the detailed description of the embodiments of the present invention below.
The preferred embodiment of the present invention is described below with reference to the accompanying drawings.
The substrate 1 is made, for example, of polycarbonate and has a circular doughnut shape. A plurality of pre-grooves 12 which extend in a circumferential direction are formed on the upper surface 11 of the substrate 1 at spaced intervals in a radial direction A. This enables a structure wherein a plurality of grooves G and lands L are provided alternately side by side. Each of the grooves G include a part of the soft magnetic layer 2 and a part of the magneto-optical recording layer 3 which are laminated onto the bottom surface of the pre-grooves 12. In this magneto-optical disc D1, these grooves G are tracks for recording data. Each of the lands L also include a part of the soft magnetic layer 2 and a part of the magneto-optical recording layer 3. However, these lands L are not tracks for recording data. The thickness of the substrate 1 is, for example, 1.2 mm. The width and the depth of each of the pre-grooves 12 are, for example, 0.18 μm and 120 nm respectively. The pitch of the pre-grooves 12 is, for example, 0.27 μm.
The soft magnetic layer 2 is, for example, made of an FeC high permeability material, the saturation magnetic flux density Bs of which is, for example, 2T. The direction of magnetization of the soft magnetic layer 2 is parallel to this layer, where the soft magnetic layer 2 aids in enabling the magnetic field generated by the magnetic head to act efficiently on the recording target section of the magneto-optical recording layer 3. The thickness of the soft magnetic layer 2 differs at the grooves G and the lands L. If the thickness t1 of the soft magnetic layer 2 of the grooves G was, for example, 100 nm, the thickness t2 of the soft magnetic layer 2 of the lands L would be, for example, 20 nm.
The magneto-optical recording layer 3 is the section which records data and has a magnetic coercive force. This magneto-optical recording layer 3 has a multi-layered structure wherein layers such as a dielectric layer or a reflecting layer are combined with a perpendicular magnetization layer in which the direction of magnetization is perpendicular to the layer. For example, these may consist of an AgPdCuSi layer, a SiN layer, a AgPdCuSi layer, a GdFeCo layer, a TbFeCo layer and a SiN layer. Such multi-layered structures are ideal for suitably recording and replaying data. The thickness of the magneto-optical recording layer 3 is, for example, 125 nm. This thickness is, for example, broken down as follows: an AgPdCuSi layer of 10 nm; a SiN layer of 5 nm; an AgPdCuSi layer of 30 nm; a GdFeCo layer of 5 nm; a TbFeCo layer of 25 nm; and a SiN layer of 50 nm.
The protective layer 4 is a section for protecting the magneto-optical recording layer 3 and is, for example, made of a transparent ultraviolet curing resin. The thickness of this protective layer 4 is, for example, 15 μm.
Next, an example of the method for manufacturing a magneto-optical disc D1 is described.
First, the substrate 1 is formed using a resin by means of injection molding. A nickel stamper, for example, is used in this process. Specified convex-concave patterns which correspond to the shape of the upper surface 11 of the substrate 1 are formed on the surface of the stamper. A cavity consistent with the shape of the substrate 1 is formed by attaching the stamper to the mold. This cavity is filled with molten polycarbonate which is then cured to form the substrate 1.
Next, the soft magnetic layer 2 is formed on the substrate 1. During this process, a soft magnetic material film 2a with a thickness to completely cover the pre-grooves 12 as shown in
Next, the magneto-optical recording layer 3 and the protective layer 4 are formed in sequence. The magneto-optical recording layer 3 can be formed by sequentially laminating the plurality of layers which make up the same onto the soft magnetic layer 2 by means of, for example, sputtering. The protective layer 4 can be formed by applying an uncured ultraviolet curing resin onto the magneto-optical recording layer 3 by means of, for example, a spin coat method. The ultraviolet curing resin is then cured by means of ultraviolet irradiation. The magneto-optical disc D1 is obtained by means of the series of steps.
Next, the operation of the magneto-optical disc D1 is described.
The thickness of the soft magnetic layer 2 differs at the grooves G and lands L, where the thickness t1 of the soft magnetic layer 2 of the grooves G which are data recording tracks is greater than the thickness t2 of the soft magnetic layer 2 of the lands L which are non-data recording tracks. On the other hand, since the material is the same over the entire area of the soft magnetic layer 2, the saturation magnetic flux density of the soft magnetic layer remains the same in each area. Accordingly, the product of the saturation magnetic flux density and the thickness of the soft magnetic layer 2 is greater at the grooves G than at the lands L. Thus, more magnetic fields are able to pass through the soft magnetic layer 2 of the grooves G than the soft magnetic layer 2 of the lands L. The magnetic focusing effect of the magnetic field can be enhanced for the grooves G, whereas the effect can be reduced for the lands L. Thus, data can be recorded suitably to the grooves G when recording data to the grooves G of the magneto-optical disc D1 by means of, for example, the magnetic field modulation method. On the other hand, recording data to the lands L becomes difficult. This results in a reduced incidence of cross-writing, in which data is mistakenly recorded to the lands L, or the non-data recording tracks. This reduction in the incidence of cross-writing enables a smaller track pitch, which is ideal for maximizing the capacity for the magneto-optical disc D1.
The inventors of the present invention proceeded to write a recording mark with a mark length of 0.15 μm onto magneto-optical disc grooves and lands having the same structure as the magneto-optical disc D1 using an optical head with an objective lens numerical aperture of 0.85 and a laser wavelength of 405 nm in order to carry out tests to investigate respective bit error rates. The results obtained from the tests are shown in
The magneto-optical disc D2 of the present embodiment differs from the above embodiment in that the lands L are data recording tracks. This magneto-optical disc D2 has a structure wherein a resin layer 5, a soft magnetic layer 2, a magneto-optical recording layer 3 and a protective layer 4 are laminated sequentially onto the substrate 1.
The upper surface 11a of the substrate 1 differs from the upper surface 11 of the substrate 1 of the magneto-optical disc D1 in that it is flat-shaped. The resin layer 5 is made of, for example, an ultraviolet curing resin, the upper surface of which have a plurality of pre-grooves 51 for the formation of grooves G and lands L. The thickness t3 of the soft magnetic layer 2 of the lands L is, for example, 100 nm, and the thickness t4 of the soft magnetic layer 2 of the grooves G is, for example, 70 nm. In contrast to the magneto-optical disc D1, the thickness t3 of the soft magnetic layer 2 of the lands L is greater than the thickness t4 of the soft magnetic layer 2 of the grooves G in the magneto-optical disc D2.
Next, an example of the method of manufacturing the magneto-optical disc D2 is described.
First, the substrate 1 is formed using resin by means of the injection molding method. Meanwhile, as shown in
Next, as shown in
Next, the soft magnetic layer 2 is transcribed onto the substrate 1. In this process, as shown in
According to the above-mentioned method of manufacture, a magneto-optical disc D2 in which the thickness t3 of the soft magnetic layer 2 of the lands L is greater than the thickness t4 of the soft magnetic layer 2 of the grooves G can be readily obtained.
As opposed to the magneto-optical disc D1, in the magneto-optical disc D2, the product of the saturation magnetic flux density and the thickness of the soft magnetic layer 2 is greater for the lands L than for the grooves G. This means that the applied magnetic field acts more efficiently on the lands L than on the grooves G. Thus, the magneto-optical disc D2 is ideal for recording data onto lands L, where any mistaken recording onto the grooves G becomes difficult. As with the magneto-optical disc D1, this suppresses the incidence of cross-writing.
The present invention is in no way limited to the above-mentioned embodiment. The structures of the respective sections of the magneto-optical recording medium concerning the present invention can be subject to various design changes. Similarly, the respective steps in the method of manufacturing the magneto-optical recording medium concerning the present invention can also be subject to various changes.
For example, the material used for the soft magnetic layer does not have to be of a FeC high permeability material, and may be of another high permeability material such as a FeCoNi alloy. Similarly, the method of forming the soft magnetic layer is not limited to combined methods of sputtering and etching processes, and may comprise a method in which an etching process is carried out following the formation of a soft magnetic material film on the substrate using, for example, an electroless plating method.
As a means of varying the product of the saturation magnetic flux density and thickness of the respective soft magnetic layers of the grooves and lands, a means of varying the saturation magnetic flux density can also be used instead of varying the thickness. More concretely, a structure may be used wherein the product of the saturation magnetic flux density and the thickness of the soft magnetic layer is varied by using material with differing saturation magnetic flux densities for the soft magnetic layer of the grooves and lands. A form of varying the respective thicknesses of the soft magnetic layer of the grooves and lands includes setting the thickness of the soft magnetic layer of either the grooves or lands to zero, or namely, having a structure wherein either the grooves or lands is not present.
The magneto-optical recording medium of the present invention is by no means limited to a so-called single-faced recording structure in which a magneto-optical recording layer is positioned only on one side of the substrate, and may also consist of a so-called double-faced recording structure in which a magneto-optical recording layer is positioned on both sides of the substrate. This type of structure enables a maximization of capacity. The substrate is not limited to one made of resin, and may also be made of, for example, glass or aluminium. Similarly, the method of forming the substrate is not limited to the injection molding method, and may consist of the so-called 2P (photo-polymer) method in which the substrate is formed using an ultraviolet curing resin.
Number | Date | Country | Kind |
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2002-371784 | Dec 2002 | JP | national |
Number | Date | Country | |
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Parent | PCT/JP03/03896 | Mar 2003 | US |
Child | 11126090 | May 2005 | US |