JPH05242528A - Optical information recording medium - Google Patents

Abstract

PURPOSE:To enable the film formation by a spin coating method and to facilitate production by forming the dyestuff material constituting a light absorptive layer so as to be insoluble in the solvent of an enhancement layer material constituting a light reflection assisting layer. CONSTITUTION:Such a combination that is entirely insoluble in the solvent of the enhancement layer material constituting the light reflection assisting layer 4 is selected for the dyestuff material constituting the light absorptive layer 3 of the optical information recording medium 1. As a result, the run-off of the light absorptive layer and the dyestuff material thereof does not arise at the time of spin coating of the enhancement layer material on the light absorptive layer and the film formation of both the light absorptive layer and the light reflection assisting layer by the spin coating method is possible. Then, the optical information recording medium with which the production is easy and which is inexpensive is obtd.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical information recording medium, in particular, a dye material constituting a light absorption layer is insoluble in a solvent of an enhancement layer material constituting a light reflection auxiliary layer. The present invention relates to an optical information recording medium.

[0002]

2. Description of the Related Art Conventionally, in a recordable compact disc type optical information recording medium, a light absorbing layer (recording layer) and a light reflecting layer are formed on a transparent substrate, and a laser beam is applied to this light absorbing layer. The optical information is recorded by applying (recording light), and the optical information is read by applying laser light (reading light) to the light absorbing layer and the light reflecting layer.

However, even if an expensive metal such as gold or silver is not used for the light reflection layer, a transparent light reflection auxiliary layer having a low refractive index is formed between the light absorption layer and the light reflection layer, and By selecting the optimum materials and film thicknesses of the light absorption layer and the light reflection auxiliary layer, cheaper aluminum is used for the light reflection layer, and recording with the light reflectance similar to gold or silver is possible. And an optical information recording medium compatible with a compact disc.

In particular, when a dye material such as an organic dye compound is used for the light absorption layer and an enhancement layer material such as a resin thin film is used for the light reflection auxiliary layer, these two layers are spin-coated. Since it can be formed by the method, complicated steps can be omitted, which is advantageous in terms of cost.

FIG. 4 shows a conventional general optical information recording medium 1
FIG. 5 is a partially cutaway perspective view of the optical information recording medium 1, and FIG.

This optical information recording medium 1 comprises a transparent substrate 2
And a light absorption layer 3 (recording layer) formed on the substrate 2,
A light reflection auxiliary layer 4 formed on the light absorption layer 3, a light reflection layer 5 formed on the light reflection auxiliary layer 4, and a protective layer 6 formed on the light reflection layer 5. ..

Particularly, as shown in FIG. 5, a pre-groove 7 is formed on the substrate 2 in a spiral shape or a concentric shape. To the left and right of the pre-groove 7, parts other than the pre-groove 7, that is, lands 8 are located.

The substrate 2 and the light absorption layer 3 are in contact with each other by the first layer boundary 9. The light absorption layer 3 and the light reflection auxiliary layer 4 are in contact with each other through the second layer boundary 10. The light reflection layer 4 and the light reflection layer 5 are in contact with each other by the third layer boundary 11.
The light reflection layer 5 and the protection layer 6 are in contact with each other by the third layer boundary 12.

When the optical information recording medium 1 is irradiated with the recording laser light (recording light) L as shown by phantom lines in FIG.
The light absorption layer 3 absorbs the energy of the recording laser light L to generate heat, and thermal deformation occurs on the substrate 2 side, so that the pits 13 can be formed. Note that an optical change may occur in the light absorption layer 3.

The substrate 2 is made of a transparent material such as polycarbonate.
In addition, it is composed of a resin having excellent impact resistance.

The light absorbing layer 3 is a layer made of a light absorbing substance formed on the tracking guide means by the pre-groove 7, and by irradiating the recording laser light L,
It is a layer accompanied by heat generation, melting, sublimation, deformation or modification.

The light absorbing layer 3 is formed by uniformly coating the surface of the substrate 2 with an organic dye such as a cyanine dye dissolved in a solvent by means of a spin coating method or the like.

In this case, the forming means is a vapor deposition method, L
Examples of the method include the B method, the spin coating method, and the like. The spin coating method is preferable because the layer thickness can be controlled by adjusting the concentration, viscosity, and solvent drying rate of the light absorption layer 3.

The light reflection auxiliary layer 4 is made of a predetermined thin film made of resin, and a predetermined light reflectance can be secured by selecting the film pressure and the refractive index of the thin film.

Although a dye material having excellent weather resistance has a large refractive index, it is difficult to secure a predetermined refractive index as an optical information recording medium. However, by selecting a material for the light reflection auxiliary layer, It is also possible to secure a predetermined refractive index.

Next, the light reflection layer 5 is a metal film, and gold, silver, copper, aluminum, or an alloy containing these is formed by means of vapor deposition, sputtering or the like.

Next, the protective layer 6 is formed of a top coat material such as a resin having excellent impact resistance similar to that of the substrate 2. For example, an ultraviolet curable resin is applied as a top coat material by a spin coat method, and this is formed by irradiating it with ultraviolet rays to cure it.

With respect to the recordable compact disc type optical information recording medium 1 having such a structure, a transparent resin is used as the light reflection auxiliary layer 4 in terms of cost and facility investment. It is desirable to form a film as a solution by spin coating.

However, when the light reflection auxiliary layer 4 is formed by the spin coating method, the following problems occur.

That is, since the light absorption layer 3 as the underlayer is very easy to flow due to the coating solvent, the light reflection auxiliary layer 4
If the coating solvent and resin are not thoroughly examined, the light absorption layer 3 will be washed away when the light reflection auxiliary layer 4 is coated.

In addition, even if it is not completely washed away, the shape of the pre-groove 7 of the light absorption layer 3 is changed when the light reflection auxiliary layer 4 is applied, and the shape is largely deviated from the intended shape design regarding leveling. There are also problems such as some.

[0022]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and in forming a light reflection auxiliary layer between a light absorption layer and a light reflection layer of an optical information recording medium, It is possible to prevent the light absorption layer from being washed away when applying the light reflection auxiliary layer, and to prevent changes in the leveling due to the solvent between the light absorption layer and the light reflection auxiliary layer. An object is to provide a recording medium.

[0023]

That is, the present invention focuses on the solubility of the dye material of the light absorption layer in the solvent of the enhancement layer material of the light reflection auxiliary layer, and the first invention is
A substrate having a light-transmitting property, a light absorbing layer formed on the substrate and made of a dye material, a light reflection auxiliary layer formed on the light absorbing layer and made of an enhancement layer material, and a light reflection auxiliary An optical information recording medium having a light reflection layer formed on a layer and a protective layer formed on the light reflection layer, wherein the dye material of the light absorption layer is an enhancement layer material of the light reflection auxiliary layer. The optical information recording medium is characterized by being completely insoluble in the solvent.

In the second invention, a part or all of the solubility parameter of the enhance layer material of the light reflection auxiliary layer is within the insoluble range of the solubility parameter of the dye material of the light absorbing layer. An optical information recording medium characterized by:

Further, a third invention is characterized in that a solvent having a solubility parameter within the insoluble range of the solubility parameter of the dye material of the light absorbing layer is used as a solvent of the enhance layer material. This is an information recording medium.

Further, in a fourth aspect of the invention, a part or all of the soluble range of the enhance layer material in the solubility domain diagram expressed by the relationship of the solubility parameter to the hydrogen bonding force is included in the insoluble range of the dye material. An optical information recording medium characterized by the above.

Furthermore, a fifth aspect of the present invention is to enhance the solvent having a solubility parameter and a hydrogen bonding force included in the insoluble range of the dye material in the solubility region diagram expressed by the relationship of the solubility parameter to the hydrogen bonding force, to the above enhancer. An optical information recording medium characterized by being used as a solvent for a layer material.

The present invention will be described in more detail below. The physical structure of the optical information recording medium according to the present invention is the same as that of the conventional optical information recording medium 1 shown in FIGS. 4 and 5,
The combination of the constituent materials of the light absorption layer 3 and the light reflection auxiliary layer 4 and the solvent of the enhancement layer material of the light reflection auxiliary layer is devised.

More specifically, a combination is selected in which the dye material forming the light absorption layer 3 is completely insoluble in the solvent of the enhancement layer material forming the light reflection auxiliary layer 4.

Alternatively, a part or all of the solubility parameter (δ value or SP value) of the enhancement layer material of the light reflection auxiliary layer 4 is within the insoluble range of the solubility parameter of the dye material of the light absorption layer 3. Select the right combination.

Alternatively, a solvent having a solubility parameter within the insoluble range of the solubility parameter of the dye material of the light absorption layer 3 is used as the solvent of the enhancement layer material.

Alternatively, in the solubility region / hydrogen bonding force (γ value) dissolution region diagram, combinations in which a part or all of the soluble range of the enhance layer material is included in the insoluble range of the dye material select.

Alternatively, the solubility parameter (δ value or SP) included in the insoluble range of the dye material in the solubility region diagram of solubility parameter / hydrogen bonding force (γ value)
Value) and a hydrogen bonding force (γ value) are used as a solvent for the enhancement layer material.

[0034]

In the optical information recording medium according to the present invention, the dye material of the light absorption layer is insoluble in the solvent of the enhancement layer material of the light reflection auxiliary layer. Therefore, when the enhancement layer material is spin-coated on the light absorption layer, the It is possible to prevent the absorption layer or the dye material thereof from being washed out, and to prevent the pregroove on the light absorption layer from being deformed.

[0035]

EXAMPLES Next, examples of the present invention will be described.

[Example 1] Thickness 1.2 mm, outer diameter 120
A substrate made of polycarbonate having an inner diameter of 15 mm and an inner diameter of 15 mm was injection-molded to form a spiral pre-groove having a width of 0.6 μm and a depth of 100 nm.

A solution of 0.2 g of rhodamine B dissolved in 10 ml of ethanol as a dye material for the light absorbing layer was applied onto this substrate by spin coating to form a dye film (light absorbing layer).

At this time, the pre-groove width on the Rhodamine B layer was 0.65 μm and the depth was 60 nm.

On this dye film, a solution of 0.2 g of styrene resin dissolved in 10 ml of cyclohexane was applied by spin coating as an enhancement layer material of the light reflection auxiliary layer to form a light reflection auxiliary layer.

Before and after the formation of the light reflection auxiliary layer, Rhodamine B
The absorption spectrum peak values were compared, but the absorbance did not change.

The styrene resin layer was washed again with cyclohexane and the pregroove width and depth on the Rhodamine B layer were compared with the initial values, but there was no change.

Further, cyclohexane was extracted from an ethanol saturated solution of Rhodamine B using an extraction solvent, and the absorption spectrum of the cyclohexane solution was measured, but the absorption spectrum of Rhodamine B was not obtained.

FIG. 1 shows the positions on the dissolution region diagram of cyclohexane and the soluble range on the dissolution region diagram of rhodamine B and styrene resin. This melting region diagram is
It is a graph which shows the relationship of a solubility parameter with respect to a hydrogen bond force.

As shown, Rhodamine B (dye material)
Has a solubility parameter of 8.8 to 24.0, a styrene resin (enhancing layer material) has a solubility parameter of 8.0 to 10.6, and cyclohexane has a solubility parameter of 8.2, and a hydrogen bond. The force was 0.1.

[Example 2] On the same substrate as in Example 1 described above, 0.2 g of tetra-tert-butylphthalocyanine Cu complex was dissolved in 10 ml of tetrachloride charcoal, and applied by spin coating to form a film. The light absorption layer was formed.

The width of the pre-groove on the light absorbing layer is 0.
The thickness was 62 μm and the depth was 72 nm.

Further, 0.2 g of propylcellulose was dissolved in 10 ml of methanol as a light reflection auxiliary layer on the light absorption layer, and a film was formed by spin coating.
A light reflection auxiliary layer was formed.

Before and after the formation of the light reflection auxiliary layer, tetra ter
The absorption spectrum peak values of the t-butylphthalocyanine Cu complex were compared, but the absorbance did not change.

The propylcellulose layer was washed again with methanol, and the pregroove width and depth on the tetra-tert-butylphthalocyanine Cu complex layer were compared with the initial values, but there was no change.

Further, a tetra-tert-butylphthalocyanine Cu complex was dissolved in tetra-salt carbon to form a saturated solution, which was then extracted with methanol as an extraction solvent, and the absorption spectrum of the methanol solution was measured.
The absorption spectrum of the rt butyl phthalocyanine Cu complex was not obtained.

Position on the above-mentioned methanol dissolution region diagram,
The soluble range of the tetra-tert-butylphthalocyanine Cu complex and propylcellulose on the dissolution region diagram are shown in FIG.

As shown in the figure, the solubility parameter of tetra-tert-butylphthalocyanine Cu complex (dye material) is 7.2 to 9.1, and the solubility parameter of propyl cellulose (enhancement layer material) is 9.4 to 14 .7
And the solubility parameter of methanol is 14.5,
And the hydrogen bonding strength was 2.9.

Comparative Example 1 0.2 g of polymethine dye (IR-820 manufactured by Nippon Kayaku Co., Ltd.) was dissolved in 10 ml of diacetone alcohol on the same substrate as in Example 1 described above. Then, a light absorption layer was formed by coating and film formation by spin coating.

The width of the pre-groove on the light absorbing layer is 0.
It was 67 μm and the depth was 54 nm.

On the light absorption layer, 0.2 g of nitrocellulose was dissolved in 10 ml of ethyl cellosolve as a light reflection auxiliary layer, and applied by spin coating.

In this spin coating step, the light absorption layer was completely removed and the substrate became colorless and transparent.

Further, when 2 milligrams of the polymethine dye was dissolved in 1 liter of ethyl cellosolve, it was colored blue green. The absorption spectrum of the ethyl cellosolve solution was measured, and the absorption spectrum of the polymethine dye was obtained. ..

FIG. 3 shows the positions on the dissolution region diagram of ethyl cellosolve and the soluble range on the dissolution region diagram of the polymethine dye and nitrocellulose described above.

As shown in the figure, the solubility parameter of the polymethine dye (dye material) is 8.5 to 13.0,
The solubility parameter of nitrocellulose (enhancement layer material) is 7.8 to 14.5, the solubility parameter of ethyl cellosolve is 9.8, and the hydrogen bonding force is 1.
It was 8.

[0060]

As described above, according to the present invention, the dye material forming the light absorbing layer is made insoluble in the solvent of the enhance layer material forming the light reflection auxiliary layer. Since the light absorption layer and the light reflection auxiliary layer can be formed by the spin coating method without being lost during spin coating, it is possible to provide an inexpensive optical information recording medium that is easy to manufacture.

[0061]

[Brief description of drawings]

FIG. 1 is a dissolution region diagram of a coated dye material, an enhancement layer material, and a solvent of the enhancement layer material in an optical information recording medium according to Example 1 of the present invention.

FIG. 2 is a dissolution region diagram of a coated dye material, an enhance layer material, and a solvent of the enhance layer material in an optical information recording medium according to Example 2 of the present invention.

FIG. 3 is a dissolution region diagram of the applied dye material, the enhancement layer material, and the solvent of the enhancement layer material in Comparative Example 1.

FIG. 4 is a partially cutaway perspective view of a conventional optical information recording medium 1.

FIG. 5 is a longitudinal sectional view of the main part of the optical information recording medium 1.

[Explanation of symbols]

1 Optical Information Recording Medium 2 Translucent Substrate 3 Light Absorption Layer (Recording Layer) 4 Light Reflection Auxiliary Layer 5 Light Reflection Layer 6 Protective Layer 7 Pregroove 8 Land 9 First Layer Boundary (Substrate 2 and Light Absorption Layer 3 10) Second layer boundary (between light absorption layer 3 and light reflection auxiliary layer 4) 11 Third layer boundary (between light reflection auxiliary layer 4 and light reflection layer 5) 12 Fourth Layer boundary (between light reflecting layer 5 and protective layer 6) 13 pits L recording laser light (recording light)

Claims (5)

[Claims] 1. A light-transmissive substrate, a light-absorbing layer formed on the substrate and made of a dye material, and a light-reflection auxiliary layer formed on the light-absorbing layer and made of an enhance layer material. An optical information recording medium having a light reflection layer formed on the light reflection auxiliary layer and a protective layer formed on the light reflection auxiliary layer, wherein the dye material of the light absorption layer is the light reflection auxiliary layer. An optical information recording medium, characterized in that it is completely insoluble in the solvent of the enhancement layer material of the layer. 2. A light-transmitting substrate, a light-absorbing layer formed on the substrate and made of a dye material, and a light-reflection auxiliary layer formed on the light-absorbing layer and made of an enhance layer material. An optical information recording medium having a light reflection layer formed on this light reflection auxiliary layer and a protective layer formed on this light reflection auxiliary layer, wherein the solubility parameter of the enhancement layer material of the light reflection auxiliary layer is An optical information recording medium, characterized in that part or all of the above is within the insoluble range of the solubility parameter of the dye material of the light absorption layer. 3. A transparent substrate, a light absorbing layer formed on the substrate and made of a dye material, and a light reflection auxiliary layer formed on the light absorbing layer and made of an enhancement layer material. An optical information recording medium having a light reflection layer formed on the light reflection auxiliary layer and a protective layer formed on the light reflection layer, wherein the solubility parameter of the dye material of the light absorption layer is insoluble. An optical information recording medium, wherein a solvent having a solubility parameter within the range is used as a solvent for the enhancement layer material. 4. A light-transmissive substrate, a light absorption layer formed on the substrate and made of a dye material, and a light reflection auxiliary layer formed on the light absorption layer and made of an enhancement layer material. An optical information recording medium having a light-reflecting layer formed on the light-reflecting auxiliary layer and a protective layer formed on the light-reflecting layer, wherein the dissolution region is expressed by the relationship of solubility parameter to hydrogen bonding force. An optical information recording medium, wherein a part or all of the soluble range of the enhance layer material in the figure is included in the insoluble range of the dye material. 5. A light-transmitting substrate, a light absorbing layer formed on the substrate and made of a dye material, and a light reflection auxiliary layer formed on the light absorbing layer and made of an enhancement layer material. An optical information recording medium having a light-reflecting layer formed on the light-reflecting auxiliary layer and a protective layer formed on the light-reflecting layer, wherein the dissolution region is expressed by the relationship of solubility parameter to hydrogen bonding force. Solvent having a solubility parameter and hydrogen bonding force included in the insoluble range of the dye material in the figure,
An optical information recording medium, which is used as a solvent for the enhancement layer material.