JP2006302494A - Optical information recording medium, and reproducing device for optical information recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize enhancement in sensitivity of reproduction for a super-resolution optical information recording medium. <P>SOLUTION: The optical information recording medium is laminated with at least a light transmitting layer 10, an information recording layer 20 and a substrate 30 in this order from a surface for incidence of reproducing light. This optical information recording medium reproduces a signal with mark length shorter than resolution limit of a reproducing device for an optical system by heating a reproducing film 21 with heat produced in a light absorbing layer 22 due to irradiation with the reproducing light. The light transmitting layer 10 has, for example, a resin layer 12 with low thermal conductivity comprising transparent acrylic adhesion resin in order to stick a polycarbonate film 11 on the information recording layer 20. The transparent acrylic adhesion resin for forming this transparent resin layer 12, compared with UV hardening resin used as material for conventional light transmitting layer, is formed with coarser organization, low in the thermal conductivity, and has a role for preserving the heat produced in the information recording layer 20. The sensitivity in the reproduction is enhanced because this enable the temperature rise for the reproducing film 21 to be performed efficiently. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an optical information recording medium for optically recording or reproducing information, and an optical information recording medium reproducing apparatus for reproducing the optical information recording medium.

  In recent years, in an optical information recording medium, it is required to increase the information recording density more and more in order to process enormous information such as images. As a solution to this problem, there is a super-resolution technique which is one of information processing improvement techniques during reproduction. Super-resolution technology is a technology that reproduces a signal with a mark length (determined by the laser wavelength and the numerical aperture of the optical system) that is less than the optical resolution limit of the playback device, thereby using a smaller mark length. Since recording is possible, the substantial recording density increases.

  Therefore, conventionally, many optical information recording media (hereinafter referred to as super-resolution media) for reproducing signals having a mark length shorter than the optical system resolution limit of the reproducing apparatus have been proposed.

  As such a technique, for example, a technique using a phase change material as a reflective film is known (Patent Document 1). The phase change material in Patent Document 1 is a kind of reproduction layer in the present application when it is used as a layer that exhibits super-resolution. In addition, not only rewritable optical recording media but also read-only media can be applied. The thermochromic dye layer whose optical characteristics (transmittance) change depending on the temperature is used as a mask layer. The technique provided on the surface is also known (Patent Document 2). Note that the mask layer is a kind of reproduction layer referred to in the present application, and is a layer that causes a super-resolution phenomenon such as artificially limiting a laser spot described later.

  In these optical information recording media, the laser spot generated by the reproduction laser irradiated on the reproduction surface has a light intensity distribution, and this utilizes the fact that a temperature distribution is generated. More specifically, in a magneto-optical recording medium using a phase change material disclosed in Patent Document 1 as a reflective film, a high-temperature region in a laser spot changes during reproduction, so that the reflection of the region is reflected. Since the rate increases remarkably, the signal intensity of the reflected light in that area becomes very large compared to the intensity of signals obtained from other areas. For this reason, the signal is reproduced in the high temperature region only, and as a result, a signal having a mark length shorter than the optical system resolution limit can be reproduced.

  Further, in the optical recording medium as disclosed in Patent Document 2, temperature or light intensity distribution is generated in the reproduction laser spot on the reproduction layer that is closer to the reproduction light incident surface than the reflection layer, thereby causing the inside of the laser spot. The distribution of optical characteristics occurs. For example, when a material that increases the transmittance when the temperature becomes high is used for the reproducing layer, only the transmittance at the high temperature portion becomes high, so that the laser spot generated on the reflective layer surface is reduced in a pseudo manner. . As a result, a signal having a mark length shorter than the optical system resolution limit can be reproduced.

  Note that these super-resolution technologies and many other super-resolution technologies use the temperature distribution generated in the laser spot as described above. Sensitivity can be improved. For this reason, in the recording medium disclosed in Patent Document 1, the temperature change efficiency of the phase change material is improved and the reproduction sensitivity is improved by sandwiching the phase change material with a dielectric material having low thermal conductivity.

As described above, a super-resolution technique and a reproduction sensitivity improvement technique have been proposed as techniques for increasing the density of optical information recording media.
JP 6-124480 A (published May 6, 1994) Japanese Patent Laid-Open No. 2001-35012 (released on February 9, 2001)

  However, in the super-resolution reproduction technology, first, the laser spot is reduced in a pseudo manner, so that the utilization efficiency of the reproduction light is reduced, and the mask layer and the phase change material are heated in order to develop the super-resolution characteristics. Therefore, there is a problem that reproduction sensitivity is deteriorated due to insufficient heat. As a countermeasure against this, the recording medium described in Patent Document 1 employs a structure in which a reproducing layer is sandwiched between dielectrics in order to reduce the thermal conductivity of the dielectrics.

  However, there is a limit to reducing the thermal conductivity of the dielectric itself, and it is difficult to say that this is a sufficient technique for improving the reproduction sensitivity of a super-resolution medium. Further, Patent Document 1 describes a structure in which a phase change material is sandwiched between a polycarbonate resin substrate having a lower thermal conductivity than a dielectric material that should have higher reproduction sensitivity and an ultraviolet curable resin, which can be read from the technical idea. Not.

  This is because when the patent document 1 was filed, the phase change material as the reproduction layer was easily deteriorated and had to be sandwiched between dielectrics. However, at present, the phase change material has been improved so that the phase change material can be sandwiched between the polycarbonate resin substrate and the ultraviolet curable resin.

  As a structure close to this structure, the reproduction sensitivity is not mentioned, but as described in Patent Document 2, the mask layer (one kind of reproduction layer) is in contact with the polycarbonate resin substrate. There is a structure. In this structure, since the polycarbonate resin has a lower thermal conductivity than the dielectric, it is apparent that the reproduction sensitivity is improved compared to the case where the polycarbonate resin is in contact with the dielectric as in the recording medium disclosed in Patent Document 1. However, even in that case, the only materials that come into contact with the proposed reproduction layer are polycarbonate resin and ultraviolet curable resin, and even with these thermal conductivities, the heat storage capacity for the reproduction layer is not sufficient, and the reproduction sensitivity is improved. There was a limit. As described above, in the conventional recording medium, the current situation is that sufficient measures are not taken to increase the heat storage capacity of the reproducing layer for the purpose of improving the reproduction feeling.

  In addition, the mask layer and phase change material exhibiting super-resolution characteristics themselves absorb the light or heat directly, so that the material itself undergoes a composition change or phase change. There is also a problem that the reproduction tends to be large and the reproduction durability is poor.

  Furthermore, the reproduction used for an optical information recording medium (hereinafter referred to as a super-resolution medium) that can reproduce a signal having a mark length smaller than the optical resolution limit of the reproduction apparatus, usually using a super-resolution reproduction technique. The film has many pigments and phase change materials, and is more expensive than the film material normally used for optical information recording media. For this reason, the super-resolution medium is also more expensive than a normal optical information recording medium (one information recording layer).

  The present invention has been made in view of the above problems, and an object thereof is to provide an optical information recording medium using a super-resolution reproduction technique that is inexpensive and excellent in reproduction sensitivity. Furthermore, an object of the present invention is to improve the reproduction durability of the optical information recording medium and to provide the optical information recording medium at a low cost.

  In order to solve the above problems, the optical information recording medium according to the present invention includes a transparent resin layer, an information recording layer, and a substrate laminated from the incident surface side on which reproduction light is incident during reproduction. An optical information recording medium capable of reproducing a signal having a mark length shorter than the optical system resolution limit of the reproducing apparatus by reproducing light irradiated at the time of reproducing, wherein the thermal conductivity of the transparent resin layer is 0 It is characterized by being larger than 0.02 W / m · K and smaller than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, the transparent resin layer made of a material having a lower thermal conductivity than the conventional transparent resin layer suppresses the decrease in the amount of heat by suppressing the conduction of heat from the information recording layer. In the above configuration, the transparent resin layer is made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K. Compared with materials having a rate of 0.15 W / m · K or more (UV curable resin, polycarbonate resin, etc.), the effect of suppressing heat conduction is high, and the information recording layer can be heated (temperature rise) efficiently.

  In the optical information recording medium, another transparent material may be laminated on the transparent resin layer. Even in that case, the transparent resin layer is sufficiently thicker than the information recording layer compared to the information recording layer. Therefore, the transparent resin layer suppresses heat conduction and efficiently heats the information recording layer (temperature increase). The effect that can be done in the same way does not change.

  In order to solve the above problems, an optical information recording medium according to the present invention includes a transparent resin layer, an information recording layer, and a substrate laminated from the incident surface side on which reproduction light is incident during reproduction. And an optical information recording medium on which a signal having a mark length shorter than the optical system resolution limit of the reproducing apparatus can be reproduced by reproducing light irradiated at the time of reproduction, and the substrate has a thermal conductivity of 0 It is characterized by being larger than 0.02 W / m · K and smaller than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, a substrate made of a material having a lower thermal conductivity than the conventional substrate suppresses a decrease in the amount of heat by suppressing the conduction of heat from the information recording layer. In the above configuration, since the substrate is made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K, the thermal conductivity used as a conventional substrate is 0. Compared with materials of 15 W / m · K or more (such as UV curable resin and polycarbonate resin), the effect of suppressing heat conduction is high, and the information recording layer can be efficiently heated (temperature rise).

  The optical information recording medium according to the present invention includes a transparent resin layer, an information recording layer, a resin layer, and a substrate laminated from the incident surface side on which reproduction light is incident during reproduction, and reproduction. An optical information recording medium capable of reproducing a signal having a mark length shorter than the optical system resolution limit of the reproducing apparatus by reproducing light sometimes irradiated, wherein the thermal conductivity of the resin layer is 0.02 W / It is characterized by being larger than m · K and smaller than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, the resin layer suppresses heat conduction from the information recording layer, thereby suppressing a decrease in the amount of heat. In the above configuration, the resin layer is made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K. Compared with materials having a conductivity of 0.15 W / m · K or more (such as UV curable resin and polycarbonate resin), the effect of suppressing heat conduction is high, and the information recording layer can be efficiently heated (temperature rise). .

  The optical information recording medium according to the present invention includes a transparent resin layer, an information recording layer, and a substrate laminated from the incident surface side on which reproduction light is incident during reproduction, and is irradiated during reproduction. An optical information recording medium capable of reproducing a signal having a mark length shorter than the optical system resolution limit of the reproducing apparatus by reproducing light, wherein both the thermal conductivity of the transparent resin layer and the substrate are 0.02 W / It is characterized by being larger than m · K and smaller than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, the transparent resin layer and the substrate suppress the heat conduction from the information recording layer, thereby suppressing a decrease in the amount of heat. In the above configuration, both the transparent resin layer and the substrate are made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K. Compared with materials with a thermal conductivity of 0.15 W / m · K or more (UV curable resin, polycarbonate resin, etc.) used as a high temperature, the effect of suppressing heat conduction is higher, and the information recording layer is heated more (temperature rise). Can be done efficiently.

  The optical information recording medium according to the present invention includes a transparent resin layer, an information recording layer, a resin layer, and a substrate laminated from the incident surface side on which reproduction light is incident during reproduction, and reproduction. An optical information recording medium capable of reproducing a signal having a mark length shorter than the optical system resolution limit of a reproducing apparatus by reproducing light sometimes irradiated, wherein the thermal conductivity of the transparent resin layer and the resin layer is Both are characterized by being larger than 0.02 W / m · K and smaller than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, the transparent resin layer and the resin layer suppress the decrease in the amount of heat by suppressing the conduction of heat from the information recording layer. In the above configuration, the transparent resin layer and the resin layer are both made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K. Compared to materials with a thermal conductivity of 0.15 W / m · K or more (UV curable resin, polycarbonate resin, etc.) used as a material, the effect of suppressing heat conduction is high, and heating of the information recording layer (temperature rise) It can be done more efficiently.

  The optical information recording medium according to the present invention includes a transparent substrate, an information recording layer, and a protective resin layer laminated from the incident surface side on which reproduction light is incident during reproduction, and is irradiated during reproduction. An optical information recording medium in which a mark length shorter than the optical system resolution limit of the reproducing apparatus can be reproduced by the reproducing light, and the thermal conductivity of the transparent substrate is greater than 0.02 W / m · K. And less than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, a transparent substrate made of a material having a lower thermal conductivity than before suppresses a decrease in the amount of heat by suppressing the conduction of heat from the information recording layer. In the above configuration, the transparent substrate is made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K, so that the thermal conductivity used as a conventional transparent substrate is used. Is higher in the effect of suppressing heat conduction than materials having a thickness of 0.15 W / m · K or more (such as UV curable resin and polycarbonate resin), and the information recording layer can be efficiently heated (temperature rise).

  In addition, the optical information recording medium according to the present invention has a transparent substrate, a transparent resin layer, an information recording layer, and a protective resin layer laminated from the incident surface side on which reproduction light is incident during reproduction. An optical information recording medium capable of reproducing a mark length shorter than the optical system resolution limit of the reproducing apparatus by reproducing light irradiated at the time of reproducing, wherein the thermal conductivity of the transparent resin layer is 0.02 W. It is characterized by being larger than / m · K and smaller than 0.15 W / m · K.

  In the above configuration, when the reproduction light is irradiated from the reproduction light incident surface side, heat is generated in the information recording layer, and the recorded information is read using the heat. In order to read information, a sufficient amount of heat is required for the information recording layer. If the amount of heat is insufficient, the reproduction sensitivity is lowered. For this reason, the transparent resin layer suppresses the reduction in the amount of heat by suppressing the conduction of heat from the information recording layer. In the above configuration, the transparent resin layer is made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K. Compared with materials having a rate of 0.15 W / m · K or more (UV curable resin, polycarbonate resin, etc.), the effect of suppressing heat conduction is high, and the information recording layer can be heated (temperature rise) efficiently.

  In any one of the optical information recording media, it is preferable that the transparent resin layer and the resin layer are made of an acrylic adhesive resin. Acrylic adhesive resin has a sparser structure than conventional UV curable resins and realizes thermal conductivity greater than 0.02 W / m · K and less than 0.15 W / m · K. Therefore, it is suitable as a material for forming the heat conduction suppressing layer.

  Any one of the above optical information recording media has an information recording layer in which the information recording layer absorbs reproduction light and converts it into heat, and is heated by heat generation of the light absorption film, and is shorter than the optical system resolution limit of the reproduction apparatus. It is preferable to include a reproducing film that can reproduce a mark length signal. In this configuration, since the reproducing film and the light absorbing film are separately formed in the information recording layer, the reproducing film itself does not change the optical characteristics by absorbing light and changing the molecular structure. Therefore, super-resolution reproduction can be performed without imposing a large burden on the reproduction film, and reproduction durability can be improved.

  In this optical information recording medium, it is preferable that the reproducing film is mainly composed of a metal oxide film. Since the metal oxide film has a characteristic in which the optical characteristics change due to a band gap change due to heat, by using such a metal oxide film as a reproduction film, a dye or the like whose optical characteristics change due to a normal composition change or phase change can be obtained. Compared with an optical information recording medium using a reproduction film using a phase change material, reproduction durability can be further improved.

  In the optical information recording medium, it is preferable that the reproducing film is a relatively inexpensive zinc oxide in a metal oxide film or a mixture containing zinc oxide as a main component. As a result, the cost of the optical information recording medium can be reduced, and furthermore, by using zinc oxide or a mixture containing zinc oxide as a main component, higher super-resolution characteristics can be obtained than when other metal oxide films are used. Therefore, the recording capacity of the optical information recording medium can be improved.

  In the optical information recording medium, the light absorbing film is preferably an inorganic substance. Thereby, compared with the light absorption film which consists of organic materials, such as a pigment | dye, durability of the light absorption film itself at the time of light absorption can be improved. Therefore, it is possible to improve the reproduction durability of the optical information recording medium.

  In the optical information recording medium, since the light absorption film is made of Si or Ge alone or an alloy containing these as a main component, the reproduction film can be heated more efficiently than other metal films. Sensitivity can be improved.

  In order to solve the above problems, an optical information recording medium reproducing device according to the present invention irradiates the information recording layer with a laser beam having a laser power capable of reproducing any of the above optical information recording media. An optical reading means for reading reflected light from the optical information recording medium is provided.

  In this optical information recording medium reproducing apparatus, the reflected light from the optical information recording medium is read by irradiating laser light having a laser power capable of reproducing the optical information recording medium by the optical reading means. Stable information reproduction is possible. In order to be able to reproduce such an optical information recording medium with higher reproduction sensitivity, sufficient reproduction is possible even if the laser power is set to a value lower than the laser power for the conventional super-resolution medium. Therefore, it is possible to provide a high-performance playback device with reduced power consumption and lower cost.

  As described above, the optical information recording medium of the present invention includes a transparent resin layer, a substrate, a resin layer made of a material having a thermal conductivity larger than 0.02 W / m · K and smaller than 0.15 W / m · K. At least one of the transparent substrates is included. Thereby, compared with each conventional layer, a higher heat suppression effect is exhibited. Therefore, it is possible to improve the reproduction sensitivity of the optical information recording medium.

  In addition, since the light absorption film and the reproduction film are formed separately, super-resolution reproduction can be performed without imposing a large burden on the reproduction film itself, and the reproduction durability can be improved. .

[Embodiment 1]
An embodiment of the present invention will be described with reference to FIGS. 1 to 6 as follows.

  FIG. 1 shows a cross-sectional structure of an optical information recording medium 1 according to the present embodiment.

  As shown in FIG. 1, the optical information recording medium 1 includes a light-transmitting layer 10, an information recording layer 20, and a substrate 30, which are stacked in this order from the light incident surface.

  The light transmissive layer 10 includes a polycarbonate film 11 and a transparent resin layer 12 so as to sufficiently transmit the reproduction light. The transparent resin layer 12 is provided for closely attaching the polycarbonate film 11 to a later-described reproducing film 21 in the information recording layer 20, and is made of an adhesive material having a sparse tissue structure containing air. As a material for forming the transparent resin layer 12, a material having a thermal conductivity lower than 0.15 W / m · K and higher than 0.02 W / m · K is used, and a transparent acrylic adhesive resin is suitable. . As described above, the transparent resin layer 12 has a function of suppressing heat conduction from the reproduction film 21.

  The acrylic adhesive resin has a thermal conductivity smaller than that of a conventional UV curable resin (0.15 W / m · K), which has a sparse structure and thereby a denser structure. In addition, the acrylic adhesive resin can make the thermal conductivity smaller by making the texture structure sparser, but it cannot be made below the thermal conductivity of air (0.02 W / m · K).

  The substrate 30 is made of a resin such as a polyolefin resin. Further, as shown in the enlarged perspective view of FIG. 2, prepits 31 are formed on the substrate 30.

  By forming the information recording layer 20 on the prepit 31, the unevenness due to the prepit 31 is reflected, and information is recorded. With such a structure, a so-called read-only optical information recording medium is configured.

  The information recording layer 20 includes a reproducing film 21 made of zinc oxide, a mixture containing zinc oxide as a main component, and a light-absorbing film 22 made of Si or Ge alone or an alloy containing these as a main component. The light absorption film 22 absorbs the reproduction light and converts it into heat that can heat the reproduction film 21. When the reproducing film 21 is heated by the heat generated in the light absorbing film 22, the optical constant of the reproducing film 21 is changed, so that a signal having a mark length shorter than the optical system resolution limit of the reproducing apparatus can be reproduced. The reproduction film 21 and the light absorption film 22 are formed by sputtering in a vacuum apparatus.

  The reproducing film 21 is preferably made of a metal oxide film having a characteristic that optical characteristics change due to a band gap change caused by heat. Thereby, the reproduction durability of the reproduction film 21 can be improved as compared with a reproduction film in a conventional recording medium using a dye or a phase change material whose optical characteristics change due to a normal composition change or phase change.

  As described above, in the optical information recording medium 1, the thermal conductivity of the transparent resin layer 12 laminated on the reproducing film 21 is lower than 0.15 W / m · K and higher than 0.02 W / m · K. It is. Thereby, the heat of the reproduction | regeneration film | membrane 21 heated by the light absorption film | membrane 22 at the time of irradiation of reproduction | regeneration light can be made difficult to escape to the polycarbonate film 11 side. Therefore, a light-transmitting layer made of a conventional material such as conventional UV curable resin (thermal conductivity 0.15 W / m · K) or polycarbonate resin (thermal conductivity 0.19 W / m · K) having a dense structure. The reproducing film 21 can be efficiently heated (temperature increase) from the optical information recording medium having the above. Therefore, the reproduction sensitivity of the information recording layer 20 can be improved.

[Example 1]
An optical information recording medium 1 according to this embodiment shown in FIG. 1 includes a polycarbonate film 11 (film thickness: 80 μm) and a transparent resin layer 12 (transparent acrylic adhesive resin, thermal conductivity: 0.03 W /) as a translucent layer 10. m · K, film thickness: 20 μm), reproduction film 21 (zinc oxide, film thickness: 155 nm) and light absorption film 22 (Si, film thickness: 50 nm) as information recording layer 20, and polyolefin resin as substrate 30 And a substrate that is laminated in this order from the light incident surface.

  In contrast, FIG. 3 shows a cross-sectional structure of an optical information recording medium 3 as a comparative example with respect to the optical information recording medium 1 of the present embodiment. In this comparative example, the same reference numerals are given to components having the same functions as the components in the optical information recording medium 1 of the present embodiment.

  As shown in FIG. 3, the optical information recording medium 3 of the comparative example includes an acrylic ultraviolet curable resin layer 13 (thermal conductivity: 0.15 W / m · K) as the light transmitting layer 10 and an information recording layer 20. And a light-absorbing film 22 (Si, film thickness: 50 nm) and a polyolefin resin substrate as the substrate 30, and are laminated in this order from the light incident surface. ing.

  Further, as shown in FIG. 2, prepits 31 on which information is recorded are formed on the substrate 30 of the optical information recording medium 3 of the comparative example, as in the optical information recording medium 1 of the present embodiment. As a result, the optical information recording medium 3 is in a state in which the projections and depressions are transferred by the prepits 31 corresponding to the information recording layer 20 by forming the information recording layer 20 on the prepits 31. Therefore, the optical information recording medium 3 is formed as a so-called read-only optical information recording medium in which the information recording layer 20 is in a state where information is recorded.

  Subsequently, the optical information recording medium 1 of the present embodiment (hereinafter referred to as “first embodiment medium” in this embodiment) and the optical information recording medium 3 of a comparative example (hereinafter referred to as “comparative medium” in this embodiment). Comparison of various characteristics with the above will be described.

  FIG. 4 shows a semiconductor laser with a wavelength of 404 nm, N.I. A. (Aperture ratio) In a disk measuring instrument having an optical system of 0.85, C in a pit having a length of 0.10 μm which is not more than the resolution limit of the disk measuring instrument in each of the first embodiment medium and the comparative medium. The dependence of / N (carrier to noise ratio) on the reproduction laser power is shown. The optical system resolution limit pit length in the disk measuring instrument is 0.12 μm.

  As is apparent from FIG. 4, the medium of the first example can obtain a higher C / N even when the reproduction laser power is lower than the medium of the comparative example. That is, it can be reproduced with a reproduction power lower than that of the comparative example medium, and it can be seen that the reproduction sensitivity is improved.

[Example 2]
Further, the optical information recording medium 1 of the present embodiment is not limited to the structure of the first example medium.

  For example, in the optical information recording medium 1 of the present embodiment (hereinafter referred to as “second embodiment medium” in the present embodiment), the translucent layer 10 can efficiently increase the temperature of the reproducing film 21. The thermal conductivity of the transparent resin layer 12 in contact with the reproduction film 21 is lower than the thermal conductivity of 0.15 W / m · K and higher than 0.02 W / m · K. It may be sufficient to transmit light, and a hard coat may be provided on the reproduction surface, or an ultraviolet curable resin or another material having a structure different from the conventional one may be used.

  Further, the layer in contact with the reproduction film 21 may be a layer made of a transparent substrate 14 as shown in FIG. 1 instead of the transparent resin layer 12. In the first embodiment medium having such a configuration, the prepits 31 provided on the substrate 30 can be provided on the transparent substrate 14. However, the material forming the layer of the transparent substrate 14 has a thermal conductivity equivalent to that of the transparent resin layer 12. Further, in the optical information recording medium 1 having such a configuration, a protective resin layer 70 may be provided instead of the substrate 30. This protective resin layer 70 is formed of an acrylic ultraviolet curable resin or the like.

  Alternatively, as shown in FIG. 1, in the light transmissive layer 10, a transparent substrate 15 may be provided instead of the polycarbonate film 11. The material forming the transparent substrate 15 may be a polyolefin resin, a polycarbonate resin, other resins that can be compression-molded, glass, metal, or the like.

  The substrate 30 may also be a polycarbonate resin, another resin that can be compression-molded, glass, metal, or the like.

As the material of the reproducing film 21, in the first embodiment medium, zinc oxide whose optical constant is changed by a temperature rise by reproducing light is used. However, an organic material such as a dye, a phase change material, and other metal oxides are used. A material made of (for example, TiO ₂ , CeO ₂ ) or a material mainly made of a metal oxide may be used. For example, in the case of an organic material such as a dye or a phase change material, although the durability of the first embodiment medium does not reach, at least the light absorption film is separated, so that the reproduction film material itself absorbs the reproduction light. It can be easily predicted that the reproduction durability is higher than that of the conventional super-resolution film structure.

Further, in the case of a material made of another metal oxide (for example, TiO ₂ , CeO ₂ ) or a material mainly made of a metal oxide, it has a reproduction durability equivalent to that of the medium of the first embodiment. The super-resolution characteristic of the zinc oxide used in the medium of one example is the best result. In addition, since the metal oxide film is generally transparent, there is an advantage that the light-absorbing film works more efficiently because of its good permeability to the light-absorbing film.

  As for the film thickness of the reproduction film 21, any material can be used. As shown in FIG. 5, the film thickness of the reproduction film 21 is 155 nm. An experimental result was obtained in which the reproduction medium 21 was compared with the second example medium having a film thickness of 50 nm in terms of reproduction sensitivity when the reproduction film 21 was made of zinc oxide.

  As can be seen from FIG. 5, the medium of the second example is slightly deteriorated in super-resolution characteristics as compared with the medium of the first example (the reached C / N at the pit length below the resolution limit is lowered). This is presumably because the effect due to the change in the optical characteristics due to the heat from the light-absorbing film described above was reduced as the film thickness was reduced. However, since the film thickness is reduced, the film is easily heated and the reproduction sensitivity is improved (reproduction is possible at a low reproduction laser power). Further, since the reproduction durability is improved as the film thickness is thicker, it can be said that the thicker one is more advantageous when the reproduction durability is included.

  Further, the material of the light absorption film 22 in the second embodiment medium may be an organic material such as a pigment, a phase change material, or another inorganic material. When an organic material such as a dye or a phase change material is used as the light absorbing film material, the light absorbing film material itself undergoes a composition change or a phase change, so the burden on the film itself is large and the medium of the first embodiment is durable. It is easy to predict that this will not be achieved. Moreover, when other inorganic substances are used as the light-absorbing film material, it can be easily predicted that the reproduction durability is the same as that of the medium of the first embodiment. Note that Ge is the most suitable material having the same reproduction sensitivity as Si.

  In addition, as for the film thickness of the light absorption film 22, the film thickness is sufficient to have sufficient reproduction durability and sufficiently exhibit super-resolution characteristics when the information recording layer 20 is reproduced, regardless of the material. If it is. Here, the information recording layer 20 in the second embodiment medium has, for example, the light absorption film 22 made of Si, and the result of comparing the reproduction durability for each film thickness is shown in FIG.

  As shown in FIG. 6, in the medium having only the film thickness of 5 nm, pits having a length of 0.10 μm, which is below the resolution limit, compared with the medium of the first embodiment of 50 nm (the optical system resolution in the disk measuring instrument). The reproduction durability at the limit pit length (0.12 μm) is deteriorated. Further, as can be seen from the fact that the initial 0.10 μm long pit C / N is low, it can be seen that the super-resolution characteristics of the medium having a film thickness of 5 nm are worse than those of the medium having a film thickness of 50 nm. As described above, even if the light absorbing film 22 is made of any material, if it is too thin, the reproduction durability is lost and the super-resolution characteristics are deteriorated.

  In the first embodiment medium, the read-only optical information recording medium is used. However, the optical information recording medium of the present invention is not limited to this. An information recording medium is also included. In these recording media, at least a recording film is added to the information recording layer.

[Embodiment 2]
Another embodiment of the present invention will be described below with reference to FIGS. In the present embodiment, components having the same functions as those in the first embodiment are denoted by the same reference numerals.

  FIG. 7 shows a cross-sectional structure of the optical information recording medium 2 according to the present embodiment.

  As shown in FIG. 7, the optical information recording medium 2 includes a translucent layer 10, an information recording layer 20, a prepit layer (resin layer) 40, and a substrate 50, which are laminated in this order from the light incident surface. Yes.

  The light transmissive layer 10 includes a polycarbonate film 11 so as to sufficiently transmit the reproduction light. The substrate 50 is formed of a resin such as a polyolefin-based resin, like the substrate 30 (FIG. 1) of the first embodiment, but does not have the prepits 31.

  As shown in FIG. 8, the prepit layer 40 is formed on the flat end surface of the substrate 50 by the 2P transfer method, and has a prepit 41 similar to the prepit 31 in the optical information recording medium 1 on the upper end surface. . Further, the prepit layer 40 is made of the same material as the material for forming the transparent resin layer 12 (FIG. 1) of Embodiment 1 (such as a curable transparent acrylic adhesive resin), and its thermal conductivity is 0. .Lower than 15 W / m · K and higher than 0.02 W / m · K.

  In the optical information recording medium 2 configured as described above, the heat conductivity of the prepit layer 40 is low, so that the heat of the information recording layer 20 can be hardly released to the substrate 50 side. Therefore, similar to the optical information recording medium 1 having the transparent resin layer 12, the reproducing film 21 is heated (temperature rise) from the optical information recording medium having a translucent layer made of a conventional material such as a conventional UV curable resin or polycarbonate resin. ) Can be performed efficiently. Therefore, the reproduction sensitivity of the optical information recording medium 1 can be improved.

  In the optical information recording medium 1 according to the first embodiment, the prepit layer 40 and the substrate 50 may be used instead of the substrate 30. In such a structure, the effect of suppressing the heat conduction of the reproducing film 21 can be obtained on both sides of the information recording layer 20, so that the reproduction sensitivity of the optical information recording medium 1 can be further improved.

  As an example, as shown in FIG. 9, only the polyolefin resin substrate 30 of the first embodiment medium is made of a curable transparent acrylic adhesive resin having a thermal conductivity of 0.03 W / m · K by 2P transfer. An optical information recording medium 4 in which the substrate 50 having the prepit layer 40 formed on the surface was changed was produced. Then, the reproduction sensitivities of the optical information recording medium 4 and the first example medium were compared by a method similar to the method of comparing the first example medium and the comparative example medium. As a result, it was confirmed that the reproduction sensitivity of the optical information recording medium 4 was improved by 0.25 mW from the reproduction sensitivity of the medium of the first example.

  The curable transparent acrylic pressure-sensitive adhesive resin has a strength capable of maintaining its shape independently after curing, and thus can be used alone as a substrate. Therefore, the prepit layer 40 formed of a curable transparent acrylic adhesive resin can also be a substrate.

  Moreover, the said Example also represents the following. That is, as described above, the first example medium uses the transparent resin layer 12 to improve the reproduction sensitivity compared to the comparative example. Further, in the optical information recording medium 4, the prepit layer 40, the transparent resin layer 12, Thus, the sensitivity was further improved by sandwiching the information recording layer 20. Therefore, even when only the prepit layer 40 is provided, it is shown that the reproduction sensitivity is improved as compared with the comparative example.

  As the optical information recording medium 2 of the present embodiment and the optical information recording medium 1 of the first embodiment, a CD-ROM (Compact Disk Read Only Memory), a CD-R (Compact Disk Recordable), a CD-RW ( Compact disk rewritable), DVD-ROM (Digital Versatile Disk Read Only Memory), DVD-RW (Digital Versatile Disk Rewritable), BD (Blu-ray Disc), BD (Blu-ray Disc) -ROM, etc. Examples of the optical information recording medium are various optical disks such as a disk, a magneto-optical disk, and a phase change disk. The present invention does not ask the recording method or size.

[Embodiment 3]
Still another embodiment of the present invention will be described with reference to FIGS. 10 and 11 as follows.

  In this embodiment, an optical information recording medium reproducing apparatus for reproducing the optical information recording medium 1 described in the first embodiment or the optical information recording media 2 and 4 described in the second embodiment will be described. FIG. 10 is a diagram showing a schematic configuration of the optical information recording medium reproducing apparatus 100. As shown in FIG.

  As shown in FIG. 10, the optical information recording medium reproducing apparatus 100 irradiates the optical information recording medium 60 as the optical information recording medium 1 or the optical information recording mediums 2 and 4 with a light beam and reflects the light beam. This is an apparatus for reproducing information recorded on the optical information recording medium 60 by detecting light. In this embodiment, the case where the optical information recording medium 60 is a disc-shaped optical disc will be described. However, the optical information recording medium 60 may not necessarily be a disc-shaped optical disc.

  As shown in FIG. 10, the optical information recording medium reproducing apparatus 100 rotates the optical information recording medium 60 with a spindle motor 101, and reads information from the optical information recording medium 60 with an optical pickup apparatus 102. . Control of the optical pickup device 102 and the spindle motor 101 is performed by the control unit 103.

  The spindle motor 101 scans the optical spot on the optical information recording medium 60 by rotating the optical information recording medium 2.

  The control unit 103 includes a signal processing unit 103a, a drive control unit 103b, and the like.

  The signal processing unit 103a records on the optical information recording medium 60 by detecting the recording information based on the electrical signal from the optical pickup device 102 obtained from the reflected light from the recording mark on the optical information recording medium 60. Read the information recorded by the mark. Further, the signal processing unit 103a generates a focus error signal and a tracking error signal, which will be described later, based on an electrical signal from the optical pickup device 102 obtained from reflected light from a recording mark on the optical information recording medium 60.

  The drive control unit 103b is a servo circuit for controlling the driving of the spindle motor 101 and the optical pickup device 102 based on an electrical signal read from the optical pickup device 102 and generated by the signal processing unit 103a and an instruction from the outside. have. In particular, the drive control unit 103b corrects the position of the objective lens 102e based on the focus error signal and the tracking error signal from the signal processing unit 103a, and sets a servo circuit for performing autofocus and tracking of the laser light as described above. Includes as a circuit.

  FIG. 11 is a diagram illustrating a configuration of the optical pickup device 102 mounted on the recording / reproducing apparatus 10.

  As shown in FIG. 11, the optical pickup device 102 includes a semiconductor laser 102a, a collimating lens 102b, a beam shaping prism (prism that makes a beam circular) 102c, a beam splitter 102d, an objective lens 102e, a lens actuator 102f, and a detection optical system. 102g.

  The optical pickup device 102 is a device that shapes the laser light emitted from the semiconductor laser 102a, which is a light source, into a beam shape and condenses it on the optical information recording medium 60. In the optical pickup device 102, a semiconductor laser 102a is used as a laser light source. However, the present invention is not limited to this, and other light sources may be used. In addition, the laser power of the semiconductor laser 102a can be set higher than the conventional laser power in order to develop the super-resolution characteristics, and can be switched to the conventional laser power. As a result, reproduction on a super-resolution medium is possible, and reproduction using a single-layer super-resolution medium with the same recording capacity and lower cost than a two-layer normal medium becomes possible. Further, since the number of layers is halved compared to the case of reproducing a two-layer normal medium having the same recording capacity, the number of times of focusing on each layer is reduced. Therefore, since the time required for focusing is shortened, the response to the reproduction command is improved.

  Laser light from the semiconductor laser 102a is converted into substantially parallel light by the collimator lens 102b, and is shaped by the beam shaping prism 102c so that the light intensity distribution is substantially circular. The substantially circular parallel light passes through the beam splitter 102d and is then focused on the optical information recording medium 60 as a light beam (incident light) by the objective lens 102e. The numerical aperture (NA) of the objective lens 102e is set to 0.65 or 0.85.

  The reflected light from the optical information recording medium 60 is branched by the beam splitter 102d and guided to the detection optical system 102g. In the detection optical system 102g, recording information, defocus information, and track position deviation information are identified from a change in the polarization direction of reflected light from the optical information recording medium 60, a change in reflected light intensity (level of reflected light level), and the like. These pieces of information are converted into electric signals. The converted electric signal is sent to the signal processing unit 103a.

  The reflected light includes reflected light from an address information mark formed by a part of the prepit 31 provided in the optical information recording medium 1 or a part of the prepit 41 provided in the optical information recording medium 2 or 4. Yes. The detection optical system 102g generates a light spot (light) formed on the light beam irradiation surface of the optical information recording medium 60 from an electrical signal obtained from the reflected light, that is, an electrical signal obtained by reproducing the address information mark. A focus error signal and a tracking error signal for the optical information recording medium 60 of the beam condensing unit are detected.

  The lens actuator 102f corrects the positional deviation of the light spot in the optical axis direction by feeding back the focus error signal. Thereby, the optical pickup device 102 can form a light spot on a desired information recording layer (information recording layer 20) in the optical information recording medium 60. Further, the lens actuator 102f corrects the positional deviation of the light spot in the track width direction by feeding back the tracking error signal. Thereby, the optical pickup device 102 can cause the optical spot to follow the target track in the optical information recording medium 60.

  In this optical information recording medium reproducing apparatus 100, information is reproduced because the optical information recording medium 60 is reproduced using the optical information recording medium 1 of the first embodiment or the optical information recording media 2 and 4 of the second embodiment. The release of heat from the recording layer 20 can be further reduced, and the temperature of the reproducing film 21 can be increased efficiently as described above. Therefore, reproduction with a lower laser power is possible, and an increase in cost of the pickup apparatus 102 can be suppressed. That is, a lower cost reproducing apparatus can be realized. In addition, the optical information recording medium reproducing apparatus 100 can perform stable information reproduction by using the optical information recording medium 60 recorded at a high density.

  The present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the claims, and embodiments obtained by appropriately combining technical means disclosed in different embodiments. Is also included in the technical scope of the present invention.

  In the optical information recording medium of the present invention, the heat conduction-suppressing layer that suppresses heat conduction from the information recording layer exhibits a higher heat-suppressing effect than conventional UV curable resins and the like. Therefore, since the reproduction sensitivity of the optical information recording medium can be improved, it can be suitably used for optical density recording.

It is sectional drawing which shows the structure of the two-layer super-resolution optical information recording medium of Embodiment 1 of this invention. It is a perspective view which shows the structure of the prepit provided in the board | substrate in the said optical information recording medium. It is sectional drawing which shows the structure of the optical information recording medium of the comparative example with respect to the optical information recording medium of Example 1 of Embodiment 1 of this invention. It is a characteristic view which shows the reproduction laser power dependence about C / N according to each reproduction film thickness of the reproduction | regeneration film | membrane of the optical information recording medium of Example 1 and a comparative example. It is a characteristic view which shows the reproduction laser power dependence about C / N according to each reproduction | regeneration film thickness of the reproduction | regeneration film | membrane of the optical information recording medium of Example 1 and 2. FIG. 10 is a characteristic diagram showing the number of reproductions dependency on C / N for each film thickness of the light absorbing film in the optical information recording medium of Example 2. It is sectional drawing which shows the structure of the optical information recording medium in Embodiment 2 of this invention. It is a perspective view which shows the structure of the prepit provided in the board | substrate in the optical information recording medium of FIG. It is sectional drawing which shows the structure of the other optical information recording medium in Embodiment 2 of this invention. It is a figure which shows schematic structure of the optical information recording medium reproducing | regenerating apparatus of Embodiment 3 of this invention. It is a figure which shows schematic structure of the optical pick-up apparatus in the said optical information recording-medium reproducing | regenerating apparatus.

Explanation of symbols

1, 2, 4 Optical information recording medium 10 Light transmitting layer 11 Polycarbonate film (light transmitting layer)
DESCRIPTION OF SYMBOLS 12 Transparent resin layer 14,15 Transparent substrate 20 Information recording layer 21 Reproduction film 22 Light absorption film 30 Substrate 31 Prepit 40 Prepit layer (resin layer)
41 Prepit 60 Optical information recording medium 70 Protective resin layer 100 Optical information recording medium reproducing device 102 Optical pickup device (optical reading means)

Claims (23)

A transparent resin layer, an information recording layer, and a substrate are laminated from the incident surface side on which reproduction light is incident during reproduction, and the optical system of the reproduction device is provided by reproduction light irradiated during reproduction. An optical information recording medium capable of reproducing a signal with a mark length shorter than the resolution limit,
An optical information recording medium, wherein the transparent resin layer has a thermal conductivity of greater than 0.02 W / m · K and less than 0.15 W / m · K.   A thin film layer made of Si, Ge, or an alloy containing either of them as a main component, a metal oxide film layer, and a transparent resin layer are laminated on a substrate, and the thermal conductivity of the transparent resin layer is 0. An optical information recording medium which is larger than 02 W / m · K and smaller than 0.15 W / m · K. A transparent resin layer, an information recording layer, and a substrate are laminated from the incident surface side on which reproduction light is incident during reproduction, and the reproduction apparatus irradiates the reproduction system with an optical system that is irradiated with the reproduction light. An optical information recording medium capable of reproducing a signal with a mark length shorter than the resolution limit,
An optical information recording medium, wherein the substrate has a thermal conductivity of more than 0.02 W / m · K and less than 0.15 W / m · K.   A thin film layer made of Si, Ge, or an alloy containing either of them as a main component, a metal oxide film layer, and a transparent resin layer are laminated on a substrate, and the thermal conductivity of the substrate is 0.02 W / m. An optical information recording medium that is larger than K and smaller than 0.15 W / m · K. A transparent resin layer, an information recording layer, a resin layer, and a substrate are laminated from the incident surface side on which reproduction light is incident during reproduction, and the reproduction device is irradiated with the reproduction light irradiated during reproduction. An optical information recording medium capable of reproducing a signal with a mark length shorter than the optical system resolution limit of
An optical information recording medium, wherein the resin layer has a thermal conductivity of greater than 0.02 W / m · K and less than 0.15 W / m · K.   On the substrate, a resin layer, a thin film layer made of Si or Ge, or an alloy mainly composed of either, a metal oxide film layer, and a transparent resin layer are laminated, and the thermal conductivity of the resin layer is An optical information recording medium characterized by being larger than 0.02 W / m · K and smaller than 0.15 W / m · K. A transparent resin layer, an information recording layer, and a substrate are laminated from the incident surface side on which reproduction light is incident during reproduction, and the optical system of the reproduction device is provided by reproduction light irradiated during reproduction. An optical information recording medium capable of reproducing a signal with a mark length shorter than the resolution limit,
An optical information recording medium, wherein the transparent resin layer and the substrate both have a thermal conductivity of greater than 0.02 W / m · K and less than 0.15 W / m · K.   A thin film layer made of Si, Ge, or an alloy containing either of them as a main component, a metal oxide film layer, and a transparent resin layer are laminated on the substrate, and the thermal conductivity of the transparent resin layer and the substrate is An optical information recording medium characterized by both being larger than 0.02 W / m · K and smaller than 0.15 W / m · K. A transparent resin layer, an information recording layer, a resin layer, and a substrate are laminated from the incident surface side on which reproduction light is incident during reproduction, and the reproduction device is irradiated with the reproduction light irradiated during reproduction. An optical information recording medium capable of reproducing a signal with a mark length shorter than the optical system resolution limit of
An optical information recording medium characterized in that both the thermal conductivity of the transparent resin layer and the resin layer are larger than 0.02 W / m · K and smaller than 0.15 W / m · K.   On the substrate, a resin layer, a thin film layer made of Si or Ge, or an alloy containing either of them as a main component, a metal oxide film layer, and a transparent resin layer are laminated, and the transparent resin layer and the resin layer are laminated. An optical information recording medium having a thermal conductivity of greater than 0.02 W / m · K and less than 0.15 W / m · K. A transparent substrate, an information recording layer, and a protective resin layer are laminated from the incident surface side on which reproduction light is incident at the time of reproduction. An optical information recording medium capable of reproducing a mark length shorter than the system resolution limit,
An optical information recording medium, wherein the transparent substrate has a thermal conductivity of greater than 0.02 W / m · K and less than 0.15 W / m · K.   On the transparent substrate, a metal oxide film layer, a thin film layer made of Si or Ge, or an alloy containing either of them as a main component, and a protective resin layer are laminated, and the thermal conductivity of the transparent substrate is 0.02 W. An optical information recording medium characterized by being larger than / m · K and smaller than 0.15 W / m · K. A transparent substrate, a transparent resin layer, an information recording layer, and a protective resin layer are laminated from the incident surface side on which reproduction light is incident at the time of reproduction, and by the reproduction light irradiated at the time of reproduction, An optical information recording medium capable of reproducing a mark length shorter than the optical system resolution limit of a reproducing apparatus,
An optical information recording medium, wherein the transparent resin layer has a thermal conductivity of greater than 0.02 W / m · K and less than 0.15 W / m · K.   On the transparent substrate, a transparent resin layer, a metal oxide film layer, a thin film layer made of Si or Ge, or an alloy containing either of them as a main component, and a protective resin layer are laminated, and the heat conduction of the transparent resin layer An optical information recording medium having a rate greater than 0.02 W / m · K and less than 0.15 W / m · K.   15. The optical information recording medium according to claim 1, wherein the transparent resin layer is formed of an acrylic pressure-sensitive adhesive material.   The optical information recording medium according to claim 5, 6, 9, or 10, wherein the resin layer is formed of an acrylic adhesive material.   The information recording layer includes at least a reproducing film for reproducing a signal having a mark length shorter than the optical system resolution limit of the reproducing apparatus, and an absorption film for absorbing the light for reproduction and converting it into heat. 14. The optical information recording medium according to claim 1, 3, 5, 7, 9, 11 or 13.   18. The optical information recording medium according to claim 17, wherein the reproducing film is mainly made of a metal oxide film.   19. The optical information recording medium according to claim 18, wherein the reproduction film is zinc oxide or a mixture containing zinc oxide as a main component.   18. The optical information recording medium according to claim 17, wherein the light absorbing film is an inorganic substance.   21. The optical information recording medium according to claim 20, wherein the light-absorbing film is made of Si or Ge alone or an alloy containing either of them as a main component.   The optical information recording medium according to claim 2, 4, 6, 8, 10, 12, or 14, wherein the metal oxide film layer is zinc oxide or a mixture containing zinc oxide as a main component.   23. An optical information recording medium reproducing apparatus, wherein the optical system resolution limit is larger than the shortest mark length of the optical information recording medium according to any one of claims 1 to 22, wherein at the time of reproduction, any one of claims 1 to 22 Or an optical reading means for irradiating the information recording layer with light for reproducing power that can be reproduced by the optical information recording medium according to claim 1 and reading reflected light from the optical information recording medium. A characteristic optical information recording medium reproducing apparatus.

Images