JPH04177639A - Magneto-optic recording film - Google Patents

Abstract

PURPOSE:To improve a magneto-optic effect to light having short wavelength by adding a light rare earth element such as Pr, Nd, Ce, and Sm, to the alter nately laminated multilayer film of a noble metal element/iron family element. CONSTITUTION:A magneto-optic recording film having multilayer structure, in which Co75Nd25 as a metallic layer I and Pt as a metallic layer II are laminated alternately respectively, is formed onto a substrate 1 made of plastic or glass. Consequently, a magneto-optic effect to light having a short wavelength is improved. Accordingly, a fine recording magnetic domain can be formed and recorded information regenerated by using light having the short wavelength, and ultra-high density magneto-optic recording can be realized. Pd, Rh, Au may be used in place of Pt of the layer II, and the same effect is acquired even by employing Fe in place of Co in the layer I and even by using Pr, Ce, Sm in place of Nd.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a magneto-optical recording material that is particularly suitable for ultra-high density optical recording in optical recording in which recording, reproduction or erasing is performed using laser light.

[Conventional technology]

With the recent development of an advanced information society, the need for high-density, large-capacity file memory is increasing. among them,
Optical recording crabs are attracting attention as a response to this demand. Currently, reproduction-only types, additional types, and replacement types have been commercialized one after another, and are widely used in fields where each type can be utilized. Among these, magneto-optical recording has been put into practical use as a rewritable type, and research and development is currently underway to improve the performance of magneto-optical disks with the aim of commercializing them for the next generation and beyond. One of these is an improvement in the recording density of information. As a method for this purpose, a method of forming fine/JX recording bits (using a laser beam with a short wavelength) is considered to be the most promising.

However, the current amount and widely used Tb-Fe-Go
As the wavelength of the light used for the magneto-optical material becomes shorter,
The magneto-optic effect, for example, reduces the Kerr rotational force by 1, and a sufficiently large reproduction output cannot be obtained, which may cause noise or errors. A known example of solving this problem is JP-A-2-6
I can cite No. 9907.

[Problem to be solved by the invention]

In the above-mentioned conventional technology, the reproduced signal that has a sufficiently large magneto-optic effect with respect to short wavelength laser light is not necessarily large enough, causing errors and noise.

An object of the present invention is to provide ultra-high-density magneto-optical recording by providing a magneto-optical recording film that has a sufficiently large magneto-optic effect for short wavelength light.

[Means to solve the problem]

Reflecting the recent development of an advanced information society, the need for high-density, large-capacity file memory is increasing, and optical memory is attracting attention as a memory that can meet this demand. Recently, magneto-optical disks have been put into practical use as rewritable optical disks. And at present, the performance has only improved.

One of the ways to do this is to improve the recording density, which is being researched in various places.

Currently, the most promising method is to use short wavelength laser light for recording and reproducing. However, in magneto-optical recording materials such as T b -F a -G o, which are currently widely used, as the wavelength of the light used becomes shorter, the magneto-optic Kerr effect becomes smaller, resulting in a smaller reproduction output. This caused errors and noise.

As one of the methods to solve this problem, a multilayer film in which Pt and Co are alternately laminated is a promising method, and is therefore being actively researched at many research institutes. For more stable playback, use Ke.
It is to exhibit a sufficiently large magneto-optical effect such as the rr effect. It has been found that the magneto-optic effect can be increased by adding a light rare earth element such as Nd, Pr, Ce, or Sm to the Co layer. Specifically, Pt, Pd, Rh,
An alloy consisting of a layer consisting of at least one element selected from Au, at least one element selected from Fe and Co, and at least one element selected from Nd, Pr, Sm, and Ce. It has been found that it is effective to use a multilayer film in which layers are laminated alternately as a recording film. A perpendicularly magnetized film exists stably when the ratio of each layer is 1:1 to 5:1. In order to further increase the magneto-optic effect, the entire recording film thickness is made to be a film thickness through which light can pass. More specifically, the thickness is preferably 500 Å or less. At the same time, a layer for reflecting light is provided on the side opposite to the direction of light incidence.

The materials used are Al and Cu.

A g r A u + P t + Rh r Cr
+ P d + P b etc. are good. What is important here is to control the thermal conductivity of the reflective film, and for this purpose, the elements shown above other than the mother element or N b + T x t T a
At least one element selected from tWtMntMo, etc. may be added. As a result, in addition to the Kerr effect, the Faraday effect is also added,
Overall, the magneto-optical effect can be increased, and the reproduction output can be increased. In addition, Tb, Dy, and HO are used to ensure further stability of the recording magnetic domain.

At least one element selected from Gd and Fe,
At least one element selected from Co and Nb
, Ti, Ta, and Cr. With such a structure, the apparent perpendicular magnetic anisotropy energy of the entire recording film is increased, and recorded information can be made to exist more stably.

[Effect]

In a magneto-optical recording film with a multilayer structure in which noble metal element layers and iron group element layers are alternately laminated, Nd, Nd,
By adding light rare earth elements such as Pr, Ce, and Sm, the magneto-optic effect for short wavelength light is further increased, which increases the reproduction output, reduces errors, improves the S/N ratio, and improves the performance of the disk. and improved reliability.

〔Example〕

The details of the present invention will be explained below using Examples 1 to 3.

[Example 1] FIG. 1 is a schematic diagram showing the cross-sectional structure of the magneto-optical recording film formed in this example. To prepare the recording film, first, a metal layer (1) is placed on a plastic or glass substrate (1).
) as Co, , Nd2. A magneto-optical recording film having a multilayer structure in which PT was alternately laminated with PT as a metal layer (n) was formed to a thickness of 500 mm. The film was formed using a binary simultaneous sputtering method, and the thickness of each layer was set to Pt:CoNd=
15 people, 9 people.

FIG. 2 shows the wavelength characteristics of the magneto-optic effect of this recording film.

As a comparative example, wavelength characteristics of a film formed using Pt and CO with the same layer ratio and total thickness as in this example are also shown. As a result, as the wavelength of the light used becomes shorter, the difference between the magneto-optic effect of the film of this example and that of the comparative example becomes larger, and λ=
At 450 nm, the difference in θ = 0.67″′ is 0.15
Next, a disk using this recording film was fabricated. A schematic diagram of its cross-sectional structure is shown in Figure 3.
1) Sputter a silicon nitride dielectric layer (
4) was formed to a thickness of 500 people (refractive index: η=2.10). Continuing, a magneto-optical recording film (5) having a structure similar to that shown in FIG. 1 was formed to a thickness of 500 by dual simultaneous sputtering.

Recording was performed on this magneto-optical disk using an optical modulation recording method.

The conditions at that time were: laser light wavelength: 450 nm, recording frequency: 25 MHz, recording laser power: 5.5 mW,
Disk rotation speed: 2400 rpm. Then, data was read out using a reproduction laser beam of 1.5 mW. When the carrier-to-noise ratio was measured, it was found that C/N=51 dB (disc position: r=30 m). The recorded magnetic domain size was determined to be 0.35 μm using a polarized light microscope, and its shape was also good.

This effect is not limited to this material system; instead of Pt, Pd, R
h, Au may be used, Fe may be used instead of CO, and Pr may be used instead of Nd.

Similar effects were obtained using Ce and Sm. Furthermore, the concentration of light rare earth elements is not limited to 25 at%, but from 15 at% to 35 at%.
It may be within the range of t%. Also, the thickness of each layer is 15 people =
The PT layer is not limited to a combination of 9 people, but may be between 10 and 30 people, and NdC.

The layer should be between 5 and 20 people. Outside this range, the perpendicular magnetic anisotropy energy becomes small, and recorded information may not be stably stored, resulting in a decrease in reliability.

[Example 2] FIG. 4 is a schematic diagram showing the cross-sectional structure of the magneto-optical disk manufactured in this example. To manufacture the disk, first, a dielectric layer (4) made of silicon nitride was formed on a plastic or glass substrate (1) to a thickness of 500 μm by sputtering. Subsequently, a multilayered magneto-optical recording film (5) having the structure shown in FIG. 1 was formed to a thickness of 300 mm. As in Example 1, the film was fabricated using a two-component simultaneous sputtering method. Next, the dielectric layer (4) of silicon nitride is
It was formed by sputtering to a film thickness of 0.0 mm. And finally, Al. Tiyu. A light reflecting layer (6) was formed to a thickness of 400 mm by sputtering.

The characteristics of the magneto-optical disk thus produced were measured. The recording conditions were: laser light wavelength = 450 nm, laser power 6.5 mW, recording frequency 25 MHz, and disk rotation speed: 240 Orpm. When reproducing with a reproducing laser power of 1.5 mW, C/N = 53 dB
(Disc position r=30m). The recorded magnetic domain size was 0.3 μm based on fR observation using a polarizing microscope. Also,
The magnetic domain shape was good and its size was stable, and no causes of noise or errors were observed. Further, by using the bit edge recording method, the recording density was further improved. In addition, override is also possible by using the magnetic field modulation recording method. Particularly in pit edge recording, control of the edge portion is important, and for this purpose the thermal conductivity of the light reflective layer must be controlled. Including AQ and Pt.

Pd, Rh, Cu, Ag, Au, Cr, Pb
, etc. are promising as reflective film materials, but their thermal conductivity is too high. Therefore, the elements shown above other than the mother element or T
x g Ta t N b + M n + W
It may be adjusted by adding rMo.

[Example 3] FIG. 5 is a schematic diagram showing the cross-sectional structure of the magneto-optical disk manufactured in this example. The disk was manufactured by sputtering a silicon nitride dielectric layer (4) to a thickness of 500 mm on a plastic or glass substrate (1) in the same manner as in Example 2. Next, a magneto-optical recording film (5) having the structure and material shown in FIG. ) as Tb2S-5FeG9
A "5CO12" 3 film (Curie temperature: 200' C1 compensation temperature: 120° C.) was formed to a thickness of 200 by sputtering.

Next, a dielectric layer (4) of silicon nitride is formed to a thickness of 100 mm by sputtering, and finally a light reflective film (6) is formed.
A film of gTi was formed to a thickness of 400 mm by sputtering.

The recording-reproducing characteristics of this magneto-optical disk were measured. The recording conditions were: laser light wavelength: 450 nm, laser power near mW, recording frequency: 25 MHz, and disk rotation speed: 2400 rp. Reproduction laser power: 1
, when reproduced at 5 mW, C/N = 53 dB (disc position: 30 m). Also, when recording-reproducing-erasing was repeated (disc position r = 30 ■, erasing laser power 8 mW)107 Even after repeating the process several times, no change in the playback output occurred, and no errors occurred. In addition, the recording film consisting of two parts, the magneto-optical recording film (5) and the perpendicularly magnetized film (7) magnetically coupled, has an apparent perpendicular magnetic anisotropy energy: Ku of 8xlQ' (erg/m
Q ) increased to 5×10' (erg/m (1)). The TbFeCoNb film increased Ku and played a role in supporting the stable existence of recorded information.

〔Effect of the invention〕

Pr in an alternately laminated multilayer film of noble metal elements/iron group elements.

By adding light rare earth elements such as Nd, Ce, and Sm, the magneto-optic effect for short wavelength light is increased. As a result, it is possible to form minute recording magnetic domains and reproduce recorded information using short wavelength light, and ultra-high density magneto-optical recording can be realized.

[Brief explanation of the drawing]

Figure 1 is a schematic diagram showing the cross-sectional structure of a magneto-optical recording film, Figure 2 is a diagram showing the dependence of Kerr rotation angle on optical wavelength, and Figures 3, 4, and 5 are cross-sectional diagrams of a magneto-optical disk. FIG. 1...Substrate, 2...Metal layer ■, 3...Metal layer ■,
4... Dielectric layer, 5... Magneto-optical recording film, 6... Light reflecting layer, 7... Perpendicular magnetization film. Rod 2 sides skin length゛entering C song)''fJ 3 mouth 4 mouth 2 nine different layer '7 1! i&4bMj!

Claims (7)

[Claims] 1. In magneto-optical recording in which recording, reproduction, or erasing is performed using laser light and an external magnetic field, Pt, Pt,
A layer consisting of at least one element selected from Pd, Rh, and Au, at least one element selected from Fe and Co, and at least one element selected from Nd, Pr, Ce, and Sm. 1. A magneto-optical recording film characterized by using a magneto-optical recording film having a multilayer structure in which layers made of an alloy of 2. In the magneto-optical recording film having a multilayer structure according to claim 1, a layer made of at least one element selected from Pt, Pd, Rh, and Au and Fe, Co
at least one element selected from among Nd, Pr
, Ce, and Sm, the ratio of each layer being 1:1 to 5:1. . 3. In the magneto-optical recording film having a multilayer structure according to claims 1 and 2, the thickness of the recording film is such that light can pass therethrough, and more preferably the film thickness is 500 Å.
A magneto-optical recording film as described below, characterized in that a layer for reflecting light is provided on a side opposite to the side on which light enters. 4. After forming a magneto-optical recording film having a multilayer structure according to claims 1 to 3, a perpendicularly magnetized film having a perpendicular magnetic anisotropy energy greater than that of the recording film is magnetically coupled. A magneto-optical recording film characterized by being formed. 5. As the perpendicular magnetization film having large perpendicular magnetic anisotropy energy as described in claim 4, Tb, Dy, H
o, at least one element selected from Gd,
At least one element selected from Fe, Co and at least one element selected from Nb, Ti, Ta, Cr
1. A magneto-optical recording film characterized by using an alloy film composed of different types of elements. 6. A magneto-optical recording film, characterized in that the layer for reflecting light according to claim 3, in addition to reflecting light, controls the temperature distribution of the magneto-optical recording film. 7. As the light reflecting layer according to claims 3 and 6, Al, Cu, Ag, Au, Pt, Cr, Pb, P
At least one element selected from d, Rh, or an element other than the parent element, or Nb, Ti, Ta, W
1. A magneto-optical recording film characterized by using an alloy with at least one element selected from among , Mn, and Mo.