JP3887331B2 - Magneto-optical recording medium and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a magneto-optical recording medium including a recording layer made of a perpendicular magnetization film, and a manufacturing method thereof.
[0002]
[Prior art]
In recent years, magneto-optical recording media have attracted attention. The magneto-optical recording medium is a rewritable recording medium that is configured using various magnetic properties of a magnetic material and has two functions of thermomagnetic recording and reproduction using a magneto-optical effect. The magneto-optical recording medium has a recording layer made of a perpendicular magnetization film, and a predetermined signal is recorded in the recording layer as a change in the magnetization direction. This recording signal is read by a predetermined optical system for reading a reproduction signal.
[0003]
In the field of magneto-optical recording media, various reproducing systems have been developed for practically reproducing signals recorded at a high density exceeding the limit of resolution in an optical system for reading reproduced signals. For example, MSR (magnetic super resolution), MAMMOS (magnetic amplifying magneto-optical system), and DWDD (domain wall displacement detection).
[0004]
For example, in a DWDD type magneto-optical recording medium, a magnetic material portion having a laminated structure of a recording layer, a reproducing layer, and an intermediate layer therebetween is provided on a predetermined substrate. Each of these three layers is a perpendicular magnetization film generally made of a rare earth-transition metal amorphous alloy, and is laminated so that exchange interaction works between two adjacent layers below the Curie temperature. The recording layer exhibits a relatively large domain wall coercivity, the reproducing layer exhibits a relatively small domain wall coercivity, and the intermediate layer has a lower Curie temperature than the other two layers.
[0005]
A predetermined signal is recorded on the recording layer along the scanning direction of the medium. Specifically, the recording layer is formed with a plurality of magnetic domains each having a predetermined length corresponding to a recording signal, the magnetization of which is alternately reversed continuously in the medium scanning direction. A plurality of domain walls standing at intervals corresponding to the recording signal are formed along the. In the reproducing layer and the intermediate layer, the recording layer and the reproducing layer are exchange-coupled via the intermediate layer under a temperature condition where the medium temperature is lower than the Curie temperature of the intermediate layer, and the medium temperature exceeds the Curie temperature of the intermediate layer. It is configured such that a domain wall motion phenomenon occurs in the reproducing layer under a predetermined temperature condition. Under a temperature condition where the medium temperature is lower than the Curie temperature of the intermediate layer, the reproducing layer exchange-coupled to the recording layer via the intermediate layer includes a magnetic domain magnetized in the same direction as the recording layer and a domain wall in the magnetic domain. And are fixed. Under a temperature condition in which the medium temperature is higher than the Curie temperature of the intermediate layer, the spontaneous magnetization of the intermediate layer disappears, and the exchange coupling between the recording layer and the reproducing layer via the intermediate layer is broken. As a result, the domain wall can move in the reproducing layer having a small domain wall coercive force. The domain wall moves to a higher temperature region when a temperature gradient exists in the reproducing layer.
[0006]
In the reproducing operation of the DWDD type magneto-optical disk in which the information track made of the magnetic material portion having the laminated structure as described above is formed, the information track is irradiated with a reproducing laser beam while rotating the disk. The information track is scanned. At this time, a temperature gradient is generated in the scanning direction in the beam irradiation region inside the information track made of the magnetic material portion. In the beam irradiation region, the magnetic wall moves to the higher temperature side in the reproducing layer at the moment when the magnetic wall of the reproducing layer passes the isothermal line of the Curie temperature in the beam irradiation region from the low temperature region to the high temperature region with the scanning. To do. When the domain wall moves in the reproducing layer in this way, the magnetization of the domain wall moving region is reversed. By detecting this magnetization reversal with a predetermined optical system as a change in the polarization plane of the reflected light, the domain wall motion is detected. By irradiating the reproducing laser beam along the information track and sequentially detecting the domain wall movement, the recording signal of the medium is read.
[0007]
In reproduction based on such a DWDD system, not the entire spot of the reproduction laser beam, but the isotherm in the beam spot (the isotherm of the Curie temperature of the intermediate layer) of the reproduction layer or the recording layer constituting the information track. Record patterns are discriminated. Therefore, in the DWDD system, even a signal recorded at a high density on the recording layer exceeding the resolution limit in the optical system for reading the reproduction signal, that is, with a recording pattern in which the minimum recording mark length is smaller than the spot diameter. Even if it exists, it can be played back. For example, even when a red laser (beam spot diameter: about 1 μm) is used as a reproducing laser beam, a recording mark having a length of 0.1 μm or less can be reproduced in principle.
[0008]
In a magneto-optical recording medium, the smaller the length of a stable recording mark (magnetic domain) formed in the recording layer, the higher the recording resolution and, consequently, the higher the recording density. In the above-described MSR, MAMMOS, and DWDD magneto-optical recording media, there is a strong demand for a high recording density of the recording layer in order to fully exhibit these reproduction resolutions. For example, realization of a recording layer capable of stably recording continuous recording marks (magnetic domains) having a length of 0.1 μm or less is desired.
[0009]
In the technical field of magnetic materials, it is known that the degree of fineness of stable magnetic domains formed in an amorphous magnetic thin film can be affected by the uneven shape of the surface on which the magnetic thin film is laminated. Specifically, there is a tendency that a smaller stable magnetic domain can be formed in the amorphous magnetic thin film formed thereon as the unevenness of moderate roughness exists on the surface to be laminated and the unevenness is finer. Are known. It is considered that due to the unevenness of the surface to be laminated, fluctuation or movement of the domain wall existing in the magnetic domain structure of the amorphous magnetic thin film is suppressed (pinning action), and as a result, the magnetic domain structure of the amorphous magnetic film is miniaturized. . Therefore, for example, in a magnetic recording medium, in order to increase the recording resolution by miniaturizing the amorphous recording magnetic layer, a dielectric film having fine irregularities on the surface on which the recording magnetic layer is formed is formed on the recording magnetic layer. There are cases where it is employed as a base film. For example, Patent Document 1 and Patent Document 2 disclose magnetic recording media that employ a recording magnetic layer underlayer.
[0010]
[Patent Document 1]
JP 2001-76329 A
[Patent Document 2]
JP 2001-134930 A
[0011]
[Problems to be solved by the invention]
However, a conventional magneto-optical recording medium is a so-called back illumination system that involves light irradiation from the substrate side during recording and reproduction, and adopts the above-described MSR system, MAMMOS system, or DWDD system as a reproduction system However, it is not practical to adopt the conventional underlayer used in the magnetic recording medium in order to increase the recording resolution by miniaturizing the magnetic domain structure inside the recording layer. In the magneto-optical recording medium, the reproducing layer or the intermediate layer and the recording layer formed on the intermediate layer need to be appropriately exchange coupled, but the conventional dielectric underlayer film used in the magnetic recording medium This is because if such a (non-magnetic material) is provided between the intermediate layer and the recording layer, such exchange coupling is eliminated.
[0012]
The present invention has been conceived under such circumstances, and an object thereof is to achieve a high recording resolution in a magneto-optical recording medium having a recording layer made of an amorphous perpendicular magnetization film.
[0013]
[Means for Solving the Problems]
According to a first aspect of the present invention, a magneto-optical recording medium is provided. The magneto-optical recording medium includes a plurality of columnar magnetic particles arranged in parallel to each other and a non-magnetic region interposed between the plurality of columnar magnetic particles, and a laminated layer formed on the granular layer, at least And a recording layer for performing a recording function.
[0014]
According to such a configuration, high recording resolution can be achieved in a magneto-optical recording medium including a recording layer made of an amorphous perpendicular magnetization film. The recording layer according to the first aspect of the present invention is made of an amorphous perpendicular magnetic film such as a rare earth-transition metal amorphous alloy perpendicular magnetic film, and plays a reproducing function only or together with the recording function. The recording layer is formed by laminating on the granular layer. That is, the recording layer is formed using a granular layer as a base film. The granular layer of the present invention comprises a plurality of columnar magnetic particles (magnetic columns) extending in the thickness direction of the layer and nonmagnetic regions interposed between the magnetic particles. The contact surface of the granular layer with the recording layer can have fine irregularities. Specifically, the contact surface may have fine irregularities by taking a form in which a part of the columnar magnetic particles protrudes from the nonmagnetic region at the contact surface of the granular layer with the recording layer. Since the recording layer is formed by depositing and growing an amorphous magnetic material with the minute convex portion of such a fine uneven surface in the granular layer as a nucleus, that is, a base point, a fine magnetic domain structure is obtained inside the recording layer. It is. The finer the magnetic domain structure inside the recording layer, the more stable recording marks (magnetic domains) can be formed in the recording layer, and therefore the recording resolution of the recording layer is improved. In addition, in the magneto-optical recording medium according to the first aspect, since the magnetic columnar magnetic particles are scattered in the granular layer, the predetermined magnetic properties that are in surface contact with the granular layer on the side opposite to the recording layer are provided. When a layer is provided, it is possible to realize a magnetic interaction such as exchange coupling between the magnetic layer and the recording layer via a granular layer or columnar magnetic particles.
[0015]
Thus, in the magneto-optical recording medium according to the first aspect of the present invention, the granular layer provided as the base film of the recording layer has irregularities for making the magnetic domain structure inside the recording layer fine with the recording layer. At the interface. Therefore, according to the magneto-optical recording medium according to the first aspect, the recording resolution of the recording layer can be appropriately improved. Such a magneto-optical recording medium is suitable for achieving high recording density.
[0016]
According to the second aspect of the present invention, another magneto-optical recording medium is provided. This magneto-optical recording medium has a recording layer for carrying a recording function, a reproducing layer for carrying a reproducing function, and the exchange coupling state of the recording layer and the reproducing layer interposed between the recording layer and the reproducing layer. An intermediate layer, a plurality of columnar magnetic particles arranged in parallel to each other, and a non-magnetic region interposed between the plurality of columnar magnetic particles, and interposed between the recording layer and the intermediate layer in the recording layer And a granular layer in contact therewith.
[0017]
According to such a configuration, in a so-called back-illumination type magneto-optical recording medium that requires a reproducing layer, a recording layer, and an intermediate layer between them, and involves irradiation of light from the substrate side during recording and reproduction, The structure which concerns on 1 side can be comprised. Therefore, according to the second aspect of the present invention, the same effect as described above with respect to the first aspect can be obtained. In the magneto-optical recording medium, a reproducing layer, an intermediate layer, a granular layer, and a recording layer are sequentially laminated from the substrate side.
[0018]
In addition, according to the second aspect, since the magnetic columnar magnetic particles are scattered in the granular layer, it is possible to realize an exchange coupling action between the recording layer and the intermediate layer via the granular layer. . Therefore, according to the second aspect, the recording layer for carrying the recording function, the reproducing layer for carrying the reproducing function, and the exchange coupling state of the recording layer and the reproducing layer interposed between the recording layer and the reproducing layer For example, in a recording layer of a magneto-optical recording medium of an MSR system, a MAMMOS system, or a DWDD system that includes an intermediate layer for changing the thickness as a component, it is possible to appropriately increase the recording resolution.
[0019]
According to the third aspect of the present invention, another magneto-optical recording medium is provided. This magneto-optical recording medium has a recording layer for carrying a recording function, a reproducing layer for carrying a reproducing function, and the exchange coupling state of the recording layer and the reproducing layer interposed between the recording layer and the reproducing layer. Including a plurality of columnar magnetic particles arranged in parallel to each other, and a nonmagnetic region interposed between the plurality of columnar magnetic particles, and a granular layer in contact with the recording layer on the side opposite to the intermediate layer And a layer.
[0020]
According to such a configuration, a so-called front illumination type magneto-magnetism that requires a reproducing layer, a recording layer, and an intermediate layer between them, and involves irradiation of light from the side opposite to the substrate during recording and reproduction. The recording medium can have the configuration according to the first aspect. Therefore, according to the third aspect of the present invention, the same effect as described above with respect to the first aspect can be obtained. In the magneto-optical recording medium, a granular layer, a recording layer, an intermediate layer, and a reproducing layer are sequentially laminated from the substrate side.
[0021]
In the first to third aspects of the present invention, preferably, in the granular layer, the columnar magnetic particles protrude from the nonmagnetic region to the recording layer. By adjusting the degree of protrusion of the columnar magnetic particles, it is possible to adjust the degree of fineness of the magnetic domain structure inside the recording layer.
[0022]
Preferably, the columnar magnetic particles are made of a rare earth-transition metal amorphous alloy and have perpendicular magnetic anisotropy. Preferably, the columnar magnetic particles and the intermediate layer are made of the same magnetic material. Alternatively, the columnar magnetic particles and the intermediate layer are made of different magnetic materials, and the Curie temperature of the columnar magnetic particles is higher than the Curie temperature of the intermediate layer. Such a configuration allows a magnetic interaction between a predetermined magnetic layer and a recording layer that are in surface contact with the granular layer on the side opposite to the recording layer while miniaturizing the magnetic domain structure inside the recording layer. It is suitable for realizing.
[0023]
Preferably, the recording layer, the intermediate layer, the reproducing layer, and the granular layer have a multilayer structure for realizing the MSR method, the MAMMOS method, or the DWDD method. The effect of improving the recording resolution based on the present invention is particularly effective when the present invention is implemented in magneto-optical recording media of the MSR, MAMMOS, and DWDD systems that have excellent reproduction resolution.
[0024]
Preferably, the average cross-sectional diameter of the plurality of columnar magnetic particles is 10 nm or less, and the average separation distance between adjacent particles in the plurality of columnar magnetic particles is 10 nm or less. Moreover, it is preferable that the thickness of the granular layer is 5 nm or less. From the standpoint of achieving good magnetism in the granular layer while miniaturizing the irregular shape on the surface of the granular layer, such a configuration is preferable.
[0025]
According to a fourth aspect of the present invention, there is provided a method for producing a magneto-optical recording medium having a laminated structure comprising at least a recording layer for performing a recording function, and a granular layer in contact with the recording layer. . This manufacturing method includes a granular layer forming step for forming a granular layer on a substrate including a plurality of columnar magnetic particles arranged in parallel to each other and a nonmagnetic region interposed between the plurality of columnar magnetic particles. Etching the exposed laminated surface of the granular layer so that the columnar magnetic particles protrude from the nonmagnetic region; and forming a recording layer by depositing a magnetic material on the granular layer; It is characterized by including. The base material is a member that serves as a base on which a granular layer is laminated, and includes a substrate alone and a substrate on which a dielectric layer or the like is already laminated. The exposed laminated surface of the granular layer is the surface of the granular layer on the side where the recording layer is formed.
[0026]
According to such a method, the magneto-optical recording medium according to the first aspect can be manufactured. Therefore, according to the fourth aspect of the present invention, the same effect as described above with respect to the first aspect can be obtained in the produced magneto-optical recording medium.
[0027]
In the fourth aspect of the present invention, preferably, in the granular layer forming step, a co-sputtering method using a nonmagnetic target for forming a nonmagnetic region together with a magnetic target for forming a columnar magnetic particle, for forming a columnar magnetic particle Sputtering method using a target composed of a mixed compact of non-magnetic material for forming a magnetic material and non-magnetic region, a magnetic target for forming columnar magnetic particles, and non-magnetic layers stacked on the magnetic target Sputtering method using a composite target including a non-magnetic chip for region formation, or for forming columnar magnetic particles stacked on the non-magnetic target for non-magnetic region formation and the non-magnetic target The granular layer is formed by a sputtering method using a composite target including the magnetic chip. According to such a sputtering method, a granular layer including a plurality of columnar magnetic particles arranged in parallel to each other and a nonmagnetic region interposed between the plurality of columnar magnetic particles can be appropriately formed.
[0028]
DETAILED DESCRIPTION OF THE INVENTION
1 and 2 show a magneto-optical recording medium X1 according to the first embodiment of the present invention. The magneto-optical recording medium X1 includes a substrate S, a recording layer 11, a reproducing layer 12, an intermediate layer 13, a granular layer 14, and dielectric layers 15 and 16, and MSR, MAMMOS, or DWDD as a reproducing method. And a back-illuminated magneto-optical disk. FIG. 1 schematically shows a partial cross section of the magneto-optical recording medium X1, and FIG. 2 shows a stacked configuration in a land portion and / or a groove portion used as an information track of the magneto-optical recording medium X1. .
[0029]
The substrate S has a predetermined concavo-convex shape including lands and grooves, and is sufficiently transmissive to the recording laser and the reproducing laser of the magneto-optical recording medium X1. Such a substrate S is made of, for example, polycarbonate (PC) resin, polymethyl methacrylate (PMMA) resin, epoxy resin, or polyolefin resin. Alternatively, as the substrate S, a glass substrate may be adopted.
[0030]
The recording layer 11 is a part that plays a recording function in the land part and / or the groove part, and is made of an amorphous alloy containing a rare earth element and a transition metal, and has perpendicular magnetic anisotropy and is magnetized in the perpendicular direction. Perpendicular magnetic film. The vertical direction means a direction perpendicular to the film surface of the magnetic film constituting the layer. The same applies to the other layers. The recording layer 11 has a domain wall coercive force larger than that of the reproducing layer 12. As the rare earth element contained in the amorphous alloy constituting the recording layer 11, Tb, Gd, Dy, Nd, Pr, or the like can be used. As the transition metal, Fe, Co, or the like can be used. More specifically, the recording layer 11 is made of, for example, TbFeCо, DyFeCо, or TbDyFeCо having a predetermined composition. The thickness of the recording layer 11 is, for example, 60 nm.
[0031]
The reproducing layer 12 is a part that plays a reproducing function in the land portion and / or the groove portion, is made of an amorphous alloy containing a rare earth element and a transition metal, and has perpendicular magnetic anisotropy and is magnetized in the vertical direction. Perpendicular magnetic film. The reproducing layer 12 has a domain wall coercive force smaller than that of the recording layer 11. The reproduction layer 12 is made of, for example, GdFeCо, GdDyFeCо, GdTbDyFeCо, NdDyFeCо, NdGdFeCо, or PrDyFeCо having a predetermined composition. The thickness of the reproduction layer 12 is, for example, 30 nm.
[0032]
The intermediate layer 13 has a function of selectively and appropriately relaying and blocking the exchange coupling acting between the recording layer 11 and the reproducing layer 12, and is made of an amorphous alloy containing a rare earth element and a transition metal, and A perpendicular magnetization film having perpendicular magnetic anisotropy and magnetized in the perpendicular direction. Further, the intermediate layer 13 has a Curie temperature lower than that of the recording layer 11 and the reproducing layer 12. The intermediate layer 13 is made of, for example, GdFe, TbFe, GdFeCо, GdDyFeCо, GdTbDyFeCо, NdDyFeCо, NdGdFeCо, or PrDyFeCо having a predetermined composition. The thickness of the intermediate layer 13 is 10 nm, for example.
[0033]
The granular layer 14 is a portion for refining the magnetic domain structure in the recording layer 11 formed thereon, and includes a plurality of columnar magnetic particles 14a and nonmagnetic regions 14b. The magnetic particles 14a are made of TbFe, for example. The nonmagnetic region 14b is made of, for example, SiO. ₂ And SiO. The granular layer 14 has a high Curie temperature that is equal to or higher than the Curie temperature of the intermediate layer 13. The plurality of magnetic particles 14a are separated from each other in parallel, and protrude to the recording layer 11 from the nonmagnetic region 14b interposed between the magnetic particles. Therefore, the contact surface of the granular layer 14 with respect to the recording layer 11 has an uneven shape. In order to appropriately miniaturize the magnetic domain structure of the recording layer 11, the average roughness Ra of the surface of the granular layer 14 having such an uneven shape is preferably 0.4 to 0.8 nm. In order to achieve such a concavo-convex shape, the average diameter in the cross section of the plurality of magnetic particles 14a is, for example, 8 to 10 nm, the average separation distance between adjacent magnetic particles is, for example, 8 to 10 nm, The protruding length of the magnetic particle 14a from the magnetic region 14b is, for example, 1 to 5 nm. Moreover, the thickness of the granular layer 14 is 4-5 nm, for example.
[0034]
The dielectric layers 15 and 16 are portions for suppressing the recording layer 11, the reproducing layer 12, the intermediate layer 13, and the granular layer 14 from being oxidized. For example, SiN, SiO ₂ , SiO, YSiO ₂ , ZnSiO ₂ , AlO, or AlN. The dielectric layer 15 may be configured as a layer having an enhancement function for apparently increasing the Kerr rotation angle of the reflected light from the reproducing layer 12. Each of the dielectric layers 15 and 16 has a thickness of, for example, 30 to 70 nm.
[0035]
The magneto-optical recording medium X1 may further include a heat dissipation layer on the dielectric layer 16. The heat dissipation layer is a part for efficiently dissipating heat generated in the recording layer 11 or the like during laser irradiation. For example, Ag, Ag alloy, Al alloy (AlTi, AlCr, etc.), Au, or Pt It is made of a high thermal conductivity material. The magneto-optical recording medium X1 may further include a predetermined protective film on the dielectric layer 16 or, if present, the heat dissipation layer.
[0036]
FIG. 3 shows a manufacturing method of the magneto-optical recording medium X1. In the manufacture of the magneto-optical recording medium X1, first, the dielectric layer 15, the reproducing layer 12, and the intermediate layer 13 are sequentially laminated on the substrate S having a predetermined land / groove shape, so that FIG. ) Is formed. Each layer can be formed by a sputtering method using a single target or a plurality of targets made of a predetermined material corresponding to each layer.
[0037]
Next, as shown in FIG. 3B, a granular structure film 14 ′ is formed on the intermediate layer 13 by sputtering. In the formation of the granular structure film 14 ', a co-sputtering method using a target made of the above-mentioned magnetic material for forming columnar magnetic particles and a target made of the above-mentioned non-magnetic material for forming a nonmagnetic region is employed. be able to. Or you may employ | adopt the sputtering method using the target which consists of a mixed compact of the above-mentioned magnetic material and the above-mentioned nonmagnetic material. Alternatively, a composite target including a target made of the above-mentioned magnetic material for forming columnar magnetic particles and a chip made of the above-mentioned non-magnetic material for forming a non-magnetic region stacked on the magnetic target. A sputtering method using may be employed. Alternatively, a composite including a target made of the above nonmagnetic material for forming a nonmagnetic region and a chip made of the above magnetic material for forming columnar magnetic particles stacked on the nonmagnetic target. A sputtering method using a target may be employed.
[0038]
In the manufacture of the magneto-optical recording medium X1, next, as shown in FIG. 3C, the magnetic particles 14a are formed on the exposed surface of the granular structure film 14 ′ by selectively etching the nonmagnetic region 14b. A predetermined length is projected from the nonmagnetic region 14b. Thereby, the granular layer 14 of the magneto-optical recording medium X1 is formed. As an etching method in this step, RF sputter etching can be employed. In the etching, as the etching gas, for example, fluorine chloride, ammonium fluoride, xenon fluoride, or hydrogen fluoride can be used depending on the combination of materials constituting the magnetic particles 14a and the nonmagnetic regions 14b. .
[0039]
Next, as shown in FIG. 3D, a recording layer 11 and a dielectric layer 16 are sequentially formed on the granular layer 14 by depositing a predetermined material on each by sputtering. In this way, the magneto-optical recording medium X1 can be manufactured.
[0040]
In the magneto-optical recording medium X1, high recording resolution can be achieved. The recording layer 11 of the magneto-optical recording medium X1 is formed by using the granular layer 14 as a base film, and the granular layer 14 includes a plurality of columnar magnetic particles 14a extending in the thickness direction of the layer and a space between the magnetic particles. And a nonmagnetic region 14b interposed therebetween. The contact surface of the granular layer 14 with the recording layer 11 has fine irregularities. Specifically, when the granular layer 14 has a form in which a part of the magnetic particles 14a protrudes from the nonmagnetic region 14b at the contact surface with the recording layer 11, the contact surface has fine irregularities. Since the recording layer 11 is formed by depositing and growing the amorphous magnetic material with the minute convex portion of such a fine uneven contact surface in the granular layer 14 as a nucleus, that is, a base point, a fine magnetic domain structure is formed inside the recording layer 11. Is obtained. The finer the magnetic domain structure in the recording layer 11, the smaller the stable recording marks (magnetic domains) can be formed in the recording layer. Therefore, high recording resolution can be achieved in the recording layer 11. Is possible.
[0041]
In addition, in the magneto-optical recording medium X1, since the granular layer 14 has magnetism due to the presence of the magnetic particles 14a, the magnetic layer is appropriately magnetically interposed between the intermediate layer 13 and the recording layer 11 via the granular layer 14. Exchange interaction can be realized. That is, the intermediate layer 13 can appropriately have a function of relaying and blocking exchange coupling that can act between the reproducing layer 12 and the recording layer 11. As a result, the MSR, MAMMOS, or DWDD playback method can be satisfactorily realized in the magneto-optical recording medium X1.
[0042]
As described above, in the magneto-optical recording medium X1, the granular layer 14 provided as the base film of the recording layer 11 has irregularities for making the magnetic domain structure inside the recording layer 11 fine at the interface with the recording layer 11. And the granular layer 14 can appropriately relay the exchange coupling acting between the intermediate layer 13 and the recording layer 11. Therefore, according to the magneto-optical recording medium X1, it is possible to appropriately improve the recording resolution in an MSR, MAMMOS, or DWDD type magneto-optical disk having excellent reproduction resolution, and as a result, appropriately increase the recording density. It can be achieved.
[0043]
4 and 5 show a magneto-optical recording medium X2 according to the second embodiment of the present invention. The magneto-optical recording medium X2 includes a substrate S, a recording layer 11, a reproducing layer 12, an intermediate layer 13, a granular layer 14, and dielectric layers 15 and 16, and MSR, MAMMOS, or DWDD as a reproducing method. And a front-illuminated magneto-optical disk. FIG. 4 schematically shows a partial cross section of the magneto-optical recording medium X2, and FIG. 5 shows a stacked configuration in a land portion and / or a groove portion used as an information track of the magneto-optical recording medium X2. . The magneto-optical recording medium X2 is different from the magneto-optical recording medium X1 in that it has a different laminated structure. The structure and constituent materials of the substrate S and each layer are the same as those described above with respect to the magneto-optical recording medium X1.
[0044]
The magneto-optical recording medium X2 may further have a heat dissipation layer on the dielectric layer 15. The constituent material of the heat dissipation layer is the same as described above with respect to the magneto-optical recording medium X1. The magneto-optical recording medium X2 may further include a predetermined protective film on the dielectric layer 15 or, if present, the heat dissipation layer.
[0045]
FIG. 6 shows a method for manufacturing the magneto-optical recording medium X2. In the manufacture of the magneto-optical recording medium X2, first, the dielectric layer 16 is laminated on the substrate S having a predetermined land / groove shape as shown in FIG. The dielectric layer 16 can be formed by a sputtering method using a single target or a plurality of targets made of a predetermined material.
[0046]
Next, as shown in FIG. 6B, a granular structure film 14 ′ including magnetic particles 14a and nonmagnetic regions 14b is formed on the dielectric layer 16 by sputtering. In forming the granular structure film 14 ', the same sputtering method as described above with respect to the method for forming the granular structure film 14' of the magneto-optical recording medium X1 can be employed.
[0047]
Next, as shown in FIG. 6C, by selectively etching the nonmagnetic region 14b, the magnetic particles 14a protrude from the nonmagnetic region 14b by a predetermined length on the exposed surface of the granular structure film 14 '. Let As an etching method in this step, RF sputter etching can be employed.
[0048]
Next, as shown in FIG. 6D, a predetermined material is deposited on each of the layers by a sputtering method, whereby a recording layer 11, an intermediate layer 13, a reproducing layer 12, and a dielectric are formed on the granular layer 14. Layer 15 is formed sequentially. In this way, the magneto-optical recording medium X2 can be manufactured.
[0049]
In the magneto-optical recording medium X2, high recording resolution can be achieved as in the magneto-optical recording medium X1. The recording layer 11 of the magneto-optical recording medium X2 is formed using the granular layer 14 as a base film, and the granular layer 14 includes a plurality of columnar magnetic particles 14a extending in the thickness direction of the layer and a space between the magnetic particles. And a nonmagnetic region 14b interposed therebetween. By taking a form in which a part of the magnetic particles 14a protrudes from the nonmagnetic region 14b at the contact surface of the granular layer 14 with the recording layer 11, the contact surface has fine irregularities. Also in the magneto-optical recording medium X2, similarly to the magneto-optical recording medium X1, the amorphous magnetic material is deposited and grown with the minute convex portion of such a fine concave-convex contact surface in the granular layer 14 as a nucleus, that is, a base point. As a result, a fine magnetic domain structure is obtained inside the recording layer 11. Therefore, high recording resolution can be achieved in the magneto-optical recording medium X2 as in the magneto-optical recording medium X1. As described above, according to the magneto-optical recording medium X2, the recording resolution can be appropriately improved in the magneto-optical disk of the MSR method, the MAMMOS method, or the DWDD method having excellent reproduction resolution, and as a result, the recording density can be appropriately increased. Can be achieved.
[0050]
【Example】
Next, examples of the present invention will be described together with comparative examples.
[0051]
[Example 1]
[Production of magneto-optical recording medium]
A magneto-optical recording medium of this example was produced as a DWDD type and back illumination type magneto-optical disk having the laminated structure shown in FIG. In the magneto-optical recording medium of this embodiment, each of the recording layer, the intermediate layer, and the reproducing layer has magnetic characteristics for realizing DWDD reproduction.
[0052]
In the production of the magneto-optical recording medium of this example, first, a SiN film was formed on a magneto-optical disk substrate (made of polycarbonate) by DC sputtering using a DC magnetron sputtering apparatus. A 70 nm thick dielectric layer (having an enhancement function) was formed. Specifically, using an Si target, Ar gas and N as sputtering gas ₂ A SiN film was formed on the substrate by reactive sputtering using a gas. The substrate has predetermined lands and grooves on the dielectric layer lamination surface. In this sputtering, Ar gas and N ₂ The gas flow ratio was 2.3: 1, the sputtering gas pressure was 0.8 Pa, and the sputtering power was 0.8 kW.
[0053]
Next, a GdFeCо amorphous alloy (Gd _{twenty five} Fe ₅₅ Cо ₂₀ ) To form a reproducing layer having a thickness of 30 nm. In this sputtering, a GdFeCо alloy target was used, Ar gas was used as the sputtering gas, the sputtering gas pressure was 0.5 Pa, and the sputtering power was 0.8 kW. Gd formed _{twenty five} Fe ₅₅ Cо ₂₀ The Curie temperature of the reproduction layer was 280 ° C.
[0054]
Next, a TbFe amorphous alloy (TbFe) is formed on the reproducing layer by DC sputtering. ₂₀ Fe ₈₀ ) To form an intermediate layer having a thickness of 10 nm. In this sputtering, a TbFe alloy target was used, Ar gas was used as the sputtering gas, the sputtering gas pressure was 0.5 Pa, and the sputtering power was 0.8 kW. Tb formed ₂₀ Fe ₈₀ The Curie temperature of the intermediate layer was 150 ° C.
[0055]
Next, Tb is formed on the intermediate layer by DC sputtering. ₂₀ Fe ₈₀ Columnar magnetic particles and SiO ₂ A granular layer having a thickness (the height of the magnetic particles) of 5 nm composed of the nonmagnetic region formed was formed. Specifically, first, a TbFe alloy target and SiO ₂ A film having a granular structure was formed by a co-sputtering method in which the target was simultaneously DC-sputtered. In this sputtering, the sputtering gas pressure is 0.5 Pa, the sputtering power of the TbFe alloy target is 0.5 kW, and SiO 2 ₂ The sputtering power of the target was 0.7 kW. Subsequently, the exposed surface of the granular structure film thus formed was etched by RF sputtering. In this sputtering, fluorine chloride was used as the etching gas, the sputtering gas pressure was 1.0 Pa, the RF input power was 300 kW, and the etching time was about 1 minute. By such an etching process, a concavo-convex shape in which the magnetic particles protrude from the nonmagnetic region by about 1 nm was formed. In this way, a granular layer having fine irregularities on the exposed surface was formed. Tb in the formed granular layer ₂₀ Fe ₈₀ The Curie temperature of the magnetic particles was 150 ° C.
[0056]
An atomic force microscope (trade name: SPA500, manufactured by Seiko Instruments Inc.) is used after the formation of the granular structure film and before the etching of the film surface in the middle of the medium preparation process of each example. Then, the surface of the granular structure film was observed, and the average separation distance between the magnetic particles was measured. This average separation distance corresponds to the average value of the shortest distance between adjacent magnetic particles.
[0057]
In the production of the magneto-optical recording medium of this example, a TbFeCо amorphous alloy (Tb) was then formed on the granular layer by DC sputtering. _{twenty five} Fe ₅₅ Cо ₂₀ ) To form a recording layer having a thickness of 60 nm. In this sputtering, a TbFeCо alloy target was used, Ar gas was used as the sputtering gas, the sputtering gas pressure was 1.0 Pa, and the sputtering power was 0.5 kW. Tb formed _{twenty five} Fe ₅₅ Cо ₂₀ The Curie temperature of the recording layer was 270 ° C.
[0058]
Next, a dielectric layer was formed by depositing SiN on the recording layer by DC sputtering. The specific conditions are the same as described above with respect to the formation of the SiN dielectric layer described above in this embodiment.
[0059]
Next, a 20 nm thick heat dissipation layer was formed by depositing AgPdCu on the dielectric layer by DC sputtering. In this sputtering, an AgPdCu target was used, Ar gas was used as the sputtering gas, the sputtering gas pressure was 0.5 Pa, and the sputtering power was 0.2 kW. As described above, the magneto-optical recording medium of this example was produced.
[0060]
[Recording and playback characteristics]
The recording / reproducing characteristics of the magneto-optical recording medium of this example were examined. Specifically, first, a recording mark having a predetermined mark length was repeatedly recorded on the information track in the magneto-optical recording medium (magneto-optical disk) of the present embodiment through a space having the same length as the recording mark. The recording process was performed by a light modulation recording method using a tester (trade name: LM330A, manufactured by Shiba Soku). The numerical aperture NA of the objective lens of this tester is 0.65, and the laser wavelength is 405 nm. In the recording process, the power of the recording laser was appropriately changed, the laser scanning speed was set to 3.0 m / s, and the applied magnetic field was set to 300 Oe. Next, the magneto-optical recording medium was reproduced, and the CNR (dB) of the reproduction signal was measured. The reproduction process was performed using the same tester (trade name: LM330A, manufactured by Shiba Soku), the laser power was set to 2.0 mW, the laser scanning speed was set to 3.0 m / s, and the applied magnetic field was set to 0 Oe. The output level of the reproduction signal was measured using a spectrum analyzer.
[0061]
In such a recording process and a subsequent reproduction process, the mark length of the recording mark is changed, and the mark lengths of 0.5 μm, 0.4 μm, 0.3 μm, 0.2 μm, 0.15 μm, 0.1 μm, 0.1 μm,. The measurement was performed for each of 08 μm and 0.06 μm, and the CNR at each recording mark length was measured. This result is represented by a line A1 in the graph of FIG. In the graph of FIG. 9, the horizontal axis represents the recording mark length (μm), and the vertical axis represents CNR (dB).
[0062]
[Comparative example]
[Production of magneto-optical recording medium]
By performing from the formation of the dielectric layer (SiN, thickness 70 nm) on the substrate to the formation of the heat dissipation layer (AgPdCu, thickness 20 nm) in the same manner as in Example 1 except that the granular layer is not formed, FIG. A magneto-optical recording medium of this comparative example having the laminated structure shown in FIG. This magneto-optical recording medium is a DWDD type and back illumination type magneto-optical disk as in the first embodiment.
[0063]
[Recording and playback characteristics]
For the magneto-optical recording medium of this comparative example, the CNR was measured for each recording mark length in the same manner as in Example 1. This result is represented by a line A2 in the graph of FIG.
[0064]
[Examples 2 to 5]
[Production of magneto-optical recording medium]
In the magneto-optical recording medium of the present invention, the finer the magnetic column structure of the granular layer (the structure in which columnar magnetic particles are dispersed in the nonmagnetic matrix region), the finer the irregularities at the interface with the recording layer in the granular layer. Therefore, the magnetic domain structure inside the recording layer tends to be miniaturized. The degree of fineness of the surface irregularities of the granular layer depends on the size (diameter) of the cross section of the magnetic particles, and the size is considered to be affected by the conditions for forming the granular structure. Accordingly, magneto-optical recording media of Examples 2 to 5 were prepared in order to examine the dependence of the average cross-sectional diameter of the magnetic particles on the sputtering power of the magnetic target in sputtering during the formation of the granular structure film.
[0065]
Specifically, in forming a granular structure film, SiO for forming a nonmagnetic region is used. ₂ The sputtering power of the target is changed to 1.0 kW instead of 0.7 kW, and the sputtering power of the TbFe target for forming magnetic particles is changed to 0.4 kW (Example 2) and 0.5 kW (Example) instead of 0.5 kW. 3) Formation of a dielectric layer (SiN, thickness 70 nm) on the substrate in the same manner as in Example 1 except that 0.7 kW (Example 4) or 0.9 kW (Example 5) was used. To the formation of the heat dissipation layer (AgPdCu, thickness 20 nm), the magneto-optical recording media of Examples 2 to 5 were produced.
[0066]
[Observation of granular structure film surface]
An atomic force microscope (trade name: SPA500, manufactured by Seiko Instruments Inc.) is used after the formation of the granular structure film and before the etching of the film surface in the middle of the medium preparation process of each example. Then, the surface of the granular structure film was observed, and the average particle diameter of the magnetic particles was measured. This average particle diameter corresponds to the average diameter in the cross section with respect to the extending direction of the columnar magnetic particles. These results are summarized in the graph of FIG.
[0067]
[Examples 6 and 7]
[Production of magneto-optical recording medium]
In the magneto-optical recording medium of the present invention, as described above, the finer the magnetic column structure of the granular layer, the finer the magnetic domain structure inside the recording layer. The degree of fineness of the surface irregularities of the granular layer depends on the average separation distance between the magnetic particles in addition to the cross-sectional size of the magnetic particles, and the distance is affected by the conditions for forming the granular structure. Conceivable. Accordingly, magneto-optical recording media of Examples 6 and 7 were prepared in order to investigate the dependence of the average separation distance between magnetic particles on the sputtering power of the nonmagnetic target in sputtering during the formation of the granular structure film.
[0068]
Specifically, in forming a granular structure film, SiO for forming a nonmagnetic region is used. ₂ A dielectric layer (SiN) on the substrate was obtained in the same manner as in Example 1 except that the sputtering power of the target was changed to 0.5 kW (Example 6) or 0.9 kW (Example 7) instead of 0.7 kW. , Thickness 70 nm) to the formation of the heat dissipation layer (AgPdCu, thickness 20 nm), the magneto-optical recording media of Examples 6 and 7 were produced.
[0069]
[Observation of granular structure film surface]
An atomic force microscope (trade name: SPA500, manufactured by Seiko Instruments Inc.) is used after the formation of the granular structure film and before the etching of the film surface in the middle of the medium preparation process of each example. Then, the surface of the granular structure film was observed, and the average separation distance between the magnetic particles was measured. These results are summarized in the graph of FIG. 11 together with the average separation measured for the magneto-optical recording medium of Example 1.
[0070]
[Evaluation]
[About CNR measurement]
From the graph of FIG. 9, it can be seen that the magneto-optical recording medium of Example 1 has higher recording resolution than the magneto-optical recording medium of the comparative example. As shown in the graph of FIG. 9, the CNR in the magneto-optical recording medium of the comparative example is significantly reduced at a recording mark length of about 0.15 μm, compared to the case where the recording mark length is 0.3 μm or more. If the mark length is 0.1 μm or less, it is less than 40 dB that can be used practically. In contrast, the CNR in the magneto-optical recording medium of Example 1 maintains a high level when the recording mark length is 0.3 μm or more up to about 0.1 μm, and the recording mark length is 0.08 μm. Even in this case, it exceeds 40 dB that can be practically used. Thus, the magneto-optical recording medium of Example 1 according to the present invention is superior in recording resolution than the magneto-optical recording medium of the comparative example.
[0071]
[About magnetic particle size]
From the graph of FIG. 10, it can be seen that the average particle size (average cross-sectional diameter) of the magnetic particles increases as the sputtering power of the magnetic target increases in co-sputtering when forming the granular structure film. By considering such a tendency, the granular layer can be formed while being appropriately miniaturized. For example, in the magneto-optical recording medium of Example 2, it was confirmed that the distribution of magnetic particles was uneven by observation of the surface of the granular structure film using an atomic force microscope. It has been confirmed that such unevenness can be eliminated by setting the sputtering power of the magnetic target in the above to 0.5 kW or more, for example.
[0072]
[Separation distance of magnetic particles]
From the graph of FIG. 11, it can be seen that the average separation distance between the magnetic particles increases as the sputtering power of the non-magnetic target increases in the co-sputtering during formation of the granular structure film. By considering such a tendency, the granular layer can be formed while being appropriately miniaturized. For example, in the magneto-optical recording medium of Example 2, it was confirmed by observation of the surface of the granular structure film using an atomic force microscope that there are scattered portions where the magnetic particles are combined. It has been confirmed that, by setting the sputtering power of the non-magnetic target in the co-sputtering to 0.7 kW or more, for example, such coupling sites can be eliminated or significantly reduced.
[0073]
As a summary of the above, the configurations of the present invention and variations thereof are listed below as supplementary notes.
[0074]
(Supplementary note 1) A granular layer including a plurality of columnar magnetic particles arranged in parallel to each other and a nonmagnetic region interposed between the plurality of columnar magnetic particles;
A magneto-optical recording medium comprising: a recording layer formed on the granular layer and having at least a recording function.
(Appendix 2) a recording layer for carrying a recording function;
A playback layer for playing playback functions;
An intermediate layer interposed between the recording layer and the reproducing layer for changing the exchange coupling state of the recording layer and the reproducing layer;
A plurality of columnar magnetic particles arranged in parallel to each other, and a non-magnetic region interposed between the plurality of columnar magnetic particles, a granular layer interposed between the recording layer and the intermediate layer and in contact with the recording layer; And a magneto-optical recording medium.
(Supplementary note 3) a recording layer for carrying a recording function;
A playback layer for playing playback functions;
An intermediate layer interposed between the recording layer and the reproducing layer for changing the exchange coupling state of the recording layer and the reproducing layer;
A plurality of columnar magnetic particles arranged in parallel to each other, and a granular layer that includes a nonmagnetic region interposed between the plurality of columnar magnetic particles and is in contact with the recording layer on a side opposite to the intermediate layer. A magneto-optical recording medium characterized by the above.
(Supplementary note 4) The magneto-optical recording medium according to any one of Supplementary notes 1 to 3, wherein in the granular layer, the columnar magnetic particles protrude from the nonmagnetic region to the recording layer.
(Supplementary note 5) The magneto-optical recording medium according to any one of supplementary notes 1 to 4, wherein the columnar magnetic particles are made of a rare earth-transition metal amorphous alloy and have perpendicular magnetic anisotropy.
(Appendix 6) The magneto-optical recording medium according to any one of appendices 1 to 5, wherein the columnar magnetic particles and the intermediate layer are made of the same magnetic material.
(Supplementary note 7) The magneto-optical recording medium according to any one of supplementary notes 1 to 5, wherein a Curie temperature of the columnar magnetic particles is higher than a Curie temperature of the intermediate layer.
(Supplementary note 8) Any one of Supplementary notes 1 to 7, wherein the recording layer, the intermediate layer, the reproducing layer, and the granular layer have a multilayer structure for realizing the MSR method, the MAMMOS method, or the DWDD method. 2. The magneto-optical recording medium described in 1.
(Appendix 9) Any one of appendices 1 to 8, wherein the plurality of columnar magnetic particles have an average cross-sectional diameter of 10 nm or less, and an average separation distance between adjacent particles in the plurality of columnar magnetic particles is 10 nm or less. The magneto-optical recording medium according to one.
(Supplementary note 10) The magneto-optical recording medium according to any one of supplementary notes 1 to 9, wherein the granular layer has a thickness of 5 nm or less.
(Appendix 11) A method for producing a magneto-optical recording medium having a laminated structure comprising at least a recording layer for performing a recording function, and a granular layer in contact with the recording layer,
On the base material, a granular layer forming step for forming a granular layer including a plurality of columnar magnetic particles arranged in parallel with each other and a nonmagnetic region interposed between the plurality of columnar magnetic particles;
Etching the exposed laminated surface of the granular layer so that the columnar magnetic particles protrude from the nonmagnetic region;
And a step of forming a recording layer by depositing a magnetic material on the granular layer.
(Supplementary Note 12) In the granular layer forming step, a co-sputtering method using a nonmagnetic target for forming a nonmagnetic region together with a magnetic target for forming a columnar magnetic particle, a magnetic material for forming a columnar magnetic particle, and a nonmagnetic region Sputtering method using a target made of mixed green compact of non-magnetic material for forming, magnetic target for forming columnar magnetic particles, and non-magnetic material for forming non-magnetic region laminated on the magnetic target A sputtering method using a composite target including a chip, or a non-magnetic target for forming a non-magnetic region and a magnetic chip for forming columnar magnetic particles stacked on the non-magnetic target. The method for producing a magneto-optical recording medium according to appendix 11, wherein the granular layer is formed by a sputtering method using a composite target.
[0075]
【The invention's effect】
According to the present invention, in the magneto-optical recording medium, the magnetic domain structure of the recording layer made of the amorphous perpendicular magnetization film can be appropriately miniaturized. Therefore, according to the present invention, in the magneto-optical recording medium, it is possible to appropriately increase the recording density by improving the recording resolution of the recording layer. The present invention is particularly effective when implemented in magneto-optical recording media of the MSR, MAMMOS, and DWDD formats that have excellent reproduction resolution.
[Brief description of the drawings]
FIG. 1 is a schematic partial sectional view of a magneto-optical recording medium according to a first embodiment of the present invention.
FIG. 2 shows a stacked structure of the magneto-optical recording medium shown in FIG.
3 shows a manufacturing method of the magneto-optical recording medium shown in FIG.
FIG. 4 is a schematic partial sectional view of a magneto-optical recording medium according to a second embodiment of the present invention.
FIG. 5 shows a stacked structure of the magneto-optical recording medium shown in FIG.
6 shows a manufacturing method of the magneto-optical recording medium shown in FIG.
FIG. 7 illustrates a stacked configuration of the magneto-optical recording medium of Example 1.
FIG. 8 shows a laminated structure of a magneto-optical recording medium of a comparative example.
FIG. 9 shows the recording mark length dependence of CNR in each magneto-optical recording medium of Example 1 and Comparative Example.
10 shows the sputter power dependence of the average cross-sectional diameter of magnetic particles obtained based on Examples 2 to 5. FIG.
11 shows the sputter power dependency of the average separation distance between magnetic particles obtained based on Examples 1, 6, and 7. FIG.
[Explanation of symbols]
X1, X2 magneto-optical recording medium
S substrate
11 Recording layer
12 Playback layer
13 Middle layer
14 Granular layer
14a Magnetic particles
14b Nonmagnetic region
15, 16 Dielectric layer

Claims (2)

A recording layer for carrying the recording function;
A playback layer for playing playback functions;
An intermediate layer interposed between the recording layer and the reproducing layer for changing the exchange coupling state of the recording layer and the reproducing layer;
A plurality of columnar magnetic particles arranged in parallel to each other, and a non-magnetic region interposed between the plurality of columnar magnetic particles, a granular layer interposed between the recording layer and the intermediate layer and in contact with the recording layer; , equipped with a,
In the granular layer, the columnar magnetic particles protrude from the nonmagnetic region to the recording layer,
The magneto-optical recording medium , wherein the recording layer is composed of a perpendicular magnetization film made of an amorphous alloy containing a rare earth element and a transition metal, and is laminated on the granular layer . A recording layer for carrying a recording function, a reproducing layer for carrying a reproducing function, and an intermediate layer interposed between the recording layer and the reproducing layer for changing the exchange coupling state of the recording layer and the reproducing layer A plurality of columnar magnetic particles arranged in parallel to each other, and a non-magnetic region interposed between the plurality of columnar magnetic particles, and interposed between the recording layer and the intermediate layer and in contact with the recording layer And in the granular layer, the columnar magnetic particles protrude from the non-magnetic region to the recording layer, and the recording layer is a perpendicular magnetization film made of an amorphous alloy containing a rare earth element and a transition metal. A method for producing a magneto-optical recording medium , which is formed by laminating on the granular layer ,
On the intermediate layer , a granular layer forming step for forming a granular layer including a plurality of columnar magnetic particles arranged in parallel to each other and a nonmagnetic region interposed between the plurality of columnar magnetic particles;
Etching the exposed laminated surface of the granular layer so that the columnar magnetic particles protrude from the nonmagnetic region;
And a step of forming a recording layer by depositing a magnetic material on the granular layer.

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