WO2011132371A1 - 光記録媒体 - Google Patents
光記録媒体 Download PDFInfo
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- WO2011132371A1 WO2011132371A1 PCT/JP2011/002036 JP2011002036W WO2011132371A1 WO 2011132371 A1 WO2011132371 A1 WO 2011132371A1 JP 2011002036 W JP2011002036 W JP 2011002036W WO 2011132371 A1 WO2011132371 A1 WO 2011132371A1
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Definitions
- the present invention relates to an optical recording medium such as an optical disc, and more particularly to an optical recording medium capable of recording at a high recording density.
- This large-capacity optical disk realizes a recording capacity of about 25 GB by setting the recording / reproducing optical wavelength to about 405 nm and the numerical aperture NA of the condenser lens of the recording / reproducing optical system to about 0.85.
- Patent Document 1 proposes an optical recording medium having a recording layer containing Te—O or the like that crystallizes at a high speed by raising the temperature to cause an optical change.
- the present invention can be applied to the above-described large-capacity optical disk type and write once type optical recording medium, suppresses deterioration of recording characteristics due to multilayering, and has the same structure as that of a single-layer recording layer.
- An object of the present invention is to provide an optical recording medium having a degree of recording characteristics.
- the optical recording medium according to the present invention has a substrate and two or more and four or less recording layers, and at least one of the recording layers includes PdO and PdO 2 . Furthermore, a specific recording layer having a composition containing at least one of fully oxidized In, Zn, Al, and Sn (that is, In 2 O 3 , ZnO, Al 2 O 3 , SnO 2 ) is used. Then, an In / Al oxide layer containing at least one of In or Al as a main component is provided adjacent to the specific recording layer.
- “having at least one of In or Al as a main component” means that an oxide layer containing In as a main component, an oxide layer containing Al as a main component, or In and Al Any oxide layer whose main component is the sum of
- the recording layer has a multilayer structure of 2 to 4 layers, and at least one recording layer is a specific recording layer, and PdO and PdO 2 are included in the composition. Shall be included.
- this specific recording layer is irradiated with laser light, PdO and PdO 2 react with each other rather than other stable oxides such as In 2 O 3 and Al 2 O 3 . That is, PdO reacts to be decomposed into Pd and O 2 and PdO 2 is decomposed into PdO and O 2 by irradiation with the recording light. O 2 is generated at this time, so that a flat thin film-like recording layer is swollen. Therefore, a recording mark having a reflectance different from that of the surrounding area is formed at the position irradiated with the recording light.
- the specific recording layer includes at least one of fully oxidized In, Zn, Al, and Sn.
- the transmittance can be accurately controlled by adjusting the composition ratio. For example, when the Zn composition ratio is increased, the transmittance decreases, and when the Al composition ratio is increased, the transmittance increases. Further, when the composition ratio of Pd is increased, the transmittance is greatly reduced. Conversely, when the composition ratio of Pd is decreased, the transmittance tends to be greatly increased. Using such a change in transmittance with respect to the composition ratio, there is an advantage that the transmittance of the recording layer can be adjusted easily and accurately.
- an In / Al oxide layer containing at least one of In or Al as a main component is provided adjacent to the specific recording layer.
- the recording power margin becomes wider.
- a large-capacity optical disk type optical recording medium can have a multilayer recording layer configuration of 2 layers or more and 4 layers or less.
- an optical recording medium having a multi-layer recording layer structure that has a recording characteristic equivalent to that of a single-layer recording layer structure in a write-once type optical recording medium that is a large-capacity optical disk.
- FIG. 1 is a schematic cross-sectional configuration diagram of an optical recording medium according to an embodiment of the present invention.
- FIG. 5 is a schematic cross-sectional configuration diagram of an optical recording medium according to another embodiment of the present invention.
- FIG. 5 is a schematic cross-sectional configuration diagram of an optical recording medium according to another embodiment of the present invention. It is a figure which shows the recording characteristic in the 1st reference example which made the specific recording layer of the optical recording medium of this invention single layer structure. It is a figure which shows the characteristic of the recording layer in the 2nd reference example which made the specific recording layer of the optical recording medium of this invention single layer structure compared with the characteristic of the recording layer of a comparative example.
- FIG. 1 is a schematic cross-sectional configuration diagram of an optical recording medium 10 according to an embodiment of the present invention. As shown in FIG. 1, in this optical recording medium 10, two recording layers 121 (L0) and 122 (L1) are formed on a substrate 11. In a multilayer recording medium, the recording layer closest to the substrate is usually L0, then L1, L2,...
- the optical recording medium 10 of the present example When the optical recording medium 10 of the present example is configured as the above-described large-capacity optical disc (Blu-ray Disc, (registered trademark)) type, it has a disk shape with a thickness of about 1.1 mm and an outer diameter of about 120 mm. A substrate 11 is used.
- the recording layers 121 and 122 are formed on the one surface side, for example, on the surface on which the unevenness as a wobbling groove is formed, via the intermediate layer 14 made of a light transmitting material.
- dielectric layers 131a and 131b, 132a and 132b are provided above or below each recording layer 121 and 122, and in the illustrated example, adjacent vertically. This dielectric layer may be provided adjacent to either the upper or lower side.
- at least one of the dielectric layers 131a, 131b, 132a, and 132b adjacent to the upper and lower sides of the specific recording layer is configured as an In / Al oxide layer mainly containing In or Al.
- a protective layer 15 made of a light transmissive material is formed on the recording layer 122.
- the thickness of the protective layer 15 is selected so that the total thickness of the layers above the recording layer 121 is about 100 ⁇ m, and the total thickness including the substrate 11 is 1.2 mm.
- the recording light incident side is the protective layer 15 side.
- the present invention is not limited to the case of a large-capacity optical disc type configuration, but a card-like substrate is used instead of a disc shape, or the thickness of the substrate 11 or the protective layer 15 is a disc shape.
- the outer diameter and the like can be appropriately selected according to the application.
- FIG. 2 and 3 are schematic cross-sectional views of optical recording media 20 and 30 according to other embodiments of the present invention.
- a configuration of an optical recording medium 20 having a recording layer having a three-layer configuration is shown.
- unevenness as a wobbling groove is formed on the substrate 21 as in the example shown in FIG. 1, and the recording layers 221 (L0) and 222 (L1) are sequentially formed on the unevenness forming surface from the substrate 21 side.
- L2 are formed through the intermediate layers 241 and 242.
- dielectric layers 231a and 231b, 232a and 232b, 233a and 233b are provided adjacent to the upper and lower sides of the recording layers 221, 222 and 223, respectively.
- At least one of the recording layers 221 to 223, preferably at least one of the recording layers 222 and 223 is configured as a specific recording layer having the above-described composition. At least one of the dielectric layers provided adjacent to the upper and lower sides of the specific recording layer is configured as an In / Al oxide layer.
- a protective layer 25 is formed on the recording layer 223 (L2). As in the example shown in FIG. 1, in the case of a large-capacity optical disc type configuration, the outer diameter and thickness of the substrate 21 and the thickness of the protective layer 25 are preferably the same as those in the example shown in FIG.
- FIG. 3 shows a configuration of the optical recording medium 30 in the case where the recording layer has four layers.
- irregularities as wobbling grooves are formed on the substrate 31 as in the example shown in FIG.
- recording layers 321 (L0), 322 (L1), 323 (L2), and 324 (L3) are formed in this order from the substrate 31 side through the intermediate layers 341, 342, and 343 on the unevenness forming surface.
- Dielectric layers 331a and 331b, 332a and 332b, 333a and 333b, 334a and 334b are provided adjacent to the upper and lower sides of the recording layers 321 to 324.
- At least one of the recording layers 321 to 324 preferably at least one of the recording layers 322 to 324 is configured as the specific recording layer having the above-described composition.
- at least one of the dielectric layers provided adjacent to the upper and lower sides of the specific recording layer is composed of an In / Al oxide layer.
- a protective layer 35 is formed on the recording layer 324 (L3). Also in this case, similarly to the example shown in FIG. 1, in the case of a large-capacity optical disk type configuration, it is preferable that the thickness and outer diameter of the substrate 31 and the thickness of the protective layer 35 are the same as those in the example shown in FIG. .
- the substrate 11 (21, 31) is made of a material such as a resin such as polycarbonate, and is formed by transferring the uneven shape of the tracking wobbling groove from the mastering master by injection molding or the like.
- the groove shape is not essential, as long as tracking is possible and crosstalk between recording tracks is appropriately suppressed.
- the recording track can be on the groove or the land as viewed from the light incident side, and the recording method is not limited.
- At least one recording layer for example, the recording layers 122, 223, 324, and the like include PdO and PdO 2 as described above. Furthermore, it is configured as a specific recording layer having a composition containing at least one of In, Zn, Al, and Sn that is completely oxidized.
- this specific recording layer is irradiated with light such as a laser having a central wavelength of about 405 nm, PdO is decomposed into Pd and O 2 , PdO 2 is decomposed into PdO and O 2 , and structurally swells due to generation of O 2. Produce. Thereby, recording marks having different reflectances from the surroundings are formed.
- the specific recording layer contains at least one of In, Zn, Al, or Sn that is completely oxidized, that is, at least one of In 2 O 3 , ZnO, Al 2 O 3 , and SnO 2 .
- increasing the Zn composition ratio decreases the transmittance
- increasing the Al composition ratio increases the transmittance.
- the composition ratio of Pd increases, the transmittance is greatly reduced.
- the composition ratio of Pd is decreased, the transmittance tends to be greatly increased.
- the transmittance of the recording layer can be adjusted easily and accurately. For this reason, when the recording layer has a multilayer structure, any recording layer can be a specific recording layer, thereby realizing good recording characteristics in an optical recording medium having a large capacity optical disk type structure and a multilayer structure. it can.
- the second recording layer 122 L1
- the second recording layer 222 or the third recording layer 223, or the second and third recording layers 222 and 223 can be specified recording layers.
- any one of the second, third, and fourth recording layers 322, 323, and 324 may be used as the specific recording layer.
- the second and third recording layers 322 and 323 or the third and fourth recording layers 323 and 324 may be used as the specific recording layer.
- the second to fourth recording layers 322 to 324 may all be specified recording layers.
- the recording layer 121 (or 221 or 321, L0) closest to the substrate 11 (21, 31) is not configured as a specific recording layer.
- other materials may be used.
- any material can be used as long as the recording characteristics as a good recording layer can be obtained when a multilayer recording layer configuration is used, and there is no particular limitation.
- a recording layer made of another write-once recording material or a rewritable recording material can be provided, or a read-only recording layer can be provided.
- the specific recording layer may contain an incomplete oxide of an element other than the element that is a complete oxide of In, Zn, Al, and Sn. In any case, it is preferable in terms of productivity if it is made of a material capable of forming a recording layer using a common film forming apparatus.
- a recording layer material containing PdO and PdO 2 can be given.
- O is contained in a larger amount than the stoichiometric composition when Zn, In, or Sn is completely oxidized (ZnO, In 2 O 3 , SnO 2 ).
- ZnO, In 2 O 3 , SnO 2 is completely oxidized
- the recording layer contains PdO or PdO 2 and has a large-capacity optical disc type configuration, good recording characteristics can be obtained, and film formation common to the specific recording layer described above can be obtained.
- a recording layer can be formed using an apparatus, which is preferable in terms of productivity.
- “element-O” means a material containing the element and oxygen as components, and includes a compound containing the element and oxygen, and an oxide (not limited to complete oxidation) of the element. .
- the In / Al oxide layer provided adjacent to the upper and lower sides or both sides of the specific recording layer may include other dielectric materials.
- other materials include Zn—O, Sn—O, Ga—O, Si—O, Ti—O, V—O, Cr—O, Nb—O, Zr—O, Hf—O, Ta—O, Examples thereof include oxides such as Bi—O (not limited to complete oxidation).
- nitrides, such as SiN and AlN, and carbides, such as SiC may also be included.
- the composition ratio of In or Al is the composition ratio of other elements excluding O, N, and C, that is, elements such as Zn, Sn, Ga, Si, Ti, V, Cr, Nb, Zr, Hf, Ta, and Bi. Is more than 30 atomic%, preferably 50 atomic% or more. When both In and Al are included, the sum of these composition ratios may be a value exceeding 30 atomic%, preferably 50 atomic% or more. When the oxide layer having such a composition is provided adjacent to the specific recording layer, the durability of the specific recording layer can be improved, and good recording characteristics can be obtained even in a multilayer structure.
- the In / Al oxide layer having such a configuration may be provided adjacent to the upper layer or the lower layer of the specific recording layer, or may be provided adjacent to the upper and lower sides.
- the reflectance and transmittance can be accurately controlled by adjusting the thickness.
- the lower layer that is, on the side opposite to the light incident side
- the recording power margin can be widened. Therefore, it is possible to maintain good recording characteristics in the specific recording layer in the case of a multilayer recording layer configuration by providing either the upper layer or the lower layer, preferably adjacent to the upper and lower sides. Further, as in the case where the dielectric layers of other materials are provided adjacent to each other, the effect of improving the durability can be obtained.
- the thickness of the dielectric layers 131a and 131b (231a, 231b,...) As In / Al oxide layers may be several nm to several tens of nm, preferably 3 nm to 50 nm. .
- the thickness is less than 3 nm, it is difficult to maintain the film thickness accuracy, and it is difficult to obtain a preferable transmittance and reflectance range in the case of a two-layer to four-layer configuration.
- a film thickness shall be 3 nm or more and 50 nm or less.
- the dielectric layer made of an oxide layer provided adjacent to the upper layer or the lower layer of the specific recording layer is an In—Sn—O layer (ITO layer), an In—Si—Zr—O layer, or the like. Can improve storage reliability.
- a dielectric layer made of an In / Al oxide layer When a dielectric layer made of an In / Al oxide layer is not provided, a dielectric layer made of another material having a function as a protective film may be provided adjacent to the specific recording layer on the side where the In / Al oxide layer is not provided.
- a light-transmitting dielectric material having a thickness of several nm to several tens of nm may be used.
- applicable materials include In—O, Zn—O, Al—O, Sn—O, Ga—O, Si—O, Ti—O, V—O, Cr—O, Nb—O, and Zr—. Examples thereof include oxides such as O, Hf—O, Ta—O, and Bi—O.
- nitrides such as SiN and AlN, and carbides such as SiC can be used. Even when these materials are used, the durability of the recording layer can be improved.
- intermediate layers 14 made of a light transmitting material are formed between the recording layers, such as between the recording layer 121 and the recording layer 122 shown in FIG.
- the material of the intermediate layer 14 (241 or the like) is sufficient if it has sufficient light transmittance that does not affect the recording characteristics, and the thickness thereof may be in a range that can suppress the interlayer crosstalk to a predetermined value or less. Examples of applicable materials include ultraviolet curable resins.
- Each recording layer 121 (122, 221...) Including the specific recording layer can be formed by vapor deposition, sputtering, or the like.
- a Pd target and one or more targets of In 2 O 3 , ZnO, Al 2 O 3 , and SnO are used.
- an alloy target having a target composition ratio may be used.
- the film is formed by sputtering while flowing Ar gas or N 2 gas.
- the bonding state between Pd and oxygen can be controlled by forming the specific recording layer using N 2 gas.
- the transmittance and reflectance of the specific recording layer can be controlled to desired values.
- the transmittance of the specific recording layer can be increased and the reflectance can be decreased.
- the specific recording layer contains PdO and PdO 2 .
- the bonding state of Pd and oxygen in the recording layer is controlled.
- the transmittance of the recording layer can be increased.
- the bonding state of Pd and oxygen in the recording layer is controlled to further increase the transmittance of the recording layer.
- the number of Pd atoms in a state of being bonded to one oxygen atom tends to be larger than that in a state of being bonded to two oxygen atoms (PdO 2 ). Is seen.
- the specific recording layer is formed, particularly when the specific recording layer is provided on the light incident side, it can be said that it is preferable to form the film by sputtering by flowing N 2 gas in addition to O 2 gas during the film formation.
- the flow rates of the oxygen gas and the nitrogen gas can be set arbitrarily, but more preferably, the flow rate of the oxygen gas is in the range of 10 sccm to 100 sccm, and the flow rate of the nitrogen gas is in the range of 2 sccm to 50 sccm.
- the dielectric layers 131a, 131b,... 334a, 334b can be similarly formed by sputtering using a material of each dielectric layer as a target.
- a photo-curing or thermosetting resin such as an ultraviolet curable resin can be used. In this case, it is formed by heating or light irradiation after coating by spin coating or the like.
- the protective layer 13 (23, 33) provided on the recording light incident side can be a heat or photo-curing resin material. These materials can be formed by coating by spin coating or the like, and then cured by heating or light irradiation, for example, ultraviolet irradiation. Alternatively, the protective layer 13 can also be formed using an ultraviolet curable resin or the like and a resin sheet such as polycarbonate, or an adhesive layer and a resin sheet such as polycarbonate.
- the information signal is generated on the surface (laser irradiation surface) of the protective layer 13 (23, 33) due to, for example, protection against mechanical shock and scratches, and adhesion of dust and fingerprints when handling by the user.
- a hard coat may be provided to protect the recording / reproduction quality.
- a silica gel fine powder mixed in order to improve mechanical strength, a solvent type, a solventless type or other ultraviolet curable resin can be used.
- the thickness is preferably about 1 ⁇ m to several ⁇ m.
- optical recording medium 10 (20, 30) having such a configuration, it was possible to obtain very good recording / reproducing characteristics as will be described in an experimental example described later. For example, sufficient characteristics as a large-capacity optical disk were obtained in terms of the reflectance, transmittance, recording sensitivity, recording margin, etc. of the reproduction signal.
- Reference example (recording characteristics of an optical recording medium having a single recording layer structure)>
- a substrate made of disk-shaped polycarbonate having an outer diameter of 120 mm and a thickness of 1.1 mm was used as the substrate of the optical recording medium.
- a lower dielectric layer made of In—Zn—O with a thickness of 15 nm
- a specific recording layer made of In—Zn—Sn—Al—Pd—O with a thickness of 40 nm
- a thickness made of In—Zn—O An upper dielectric layer having a thickness of 15 nm was formed.
- a protective layer having a thickness of 100 ⁇ m made of an ultraviolet curable resin was formed thereon as a so-called cover layer on the outermost surface of the recording light incident side.
- Each layer was formed using a target. In 2 O 3 and ZnO are used as targets for forming the lower and upper dielectric layers, and In 2 O 3 , ZnO, SnO, and Al 2 O 3 are used as targets for forming the specific recording layer. , Pd was used. In each layer, the composition was adjusted by controlling the sputtering power of each target.
- the gas flow rate during sputtering film formation is Ar: 70 sccm and O 2 : 30 sccm during film formation of the dielectric layer, and Ar: 70 sccm, O 2 : 30 sccm and N 2 : 10 sccm during film formation of the recording layer. did.
- the optical recording medium On the optical recording medium thus produced, continuous 5 tracks were recorded at 1 ⁇ speed recording (clock 66 MHz, linear velocity 4.92 m / s) in the Blu-ray® Disc (registered trademark) evaluation apparatus, The jitter of the track was measured.
- the wavelength of the recording light is 405 nm
- the numerical aperture NA of the condenser lens is 0.85
- the recording capacity per layer is about 25 GB.
- FIG. 4 shows the jitter recording characteristics of this optical recording medium.
- the reflectance of the recording layer of this optical recording medium can be controlled by the composition and thickness of the recording layer, and the thickness of the dielectric layer provided adjacent to the top and bottom. Further, the transmittance can be controlled mainly by the composition of the recording layer. For example, the transmittance can be gradually increased as the additive amount of Al is increased. On the contrary, as the amount of Zn increases, the transmittance gradually decreases. On the other hand, the transmittance of Pd is greatly reduced when the addition amount is increased, and the transmittance is greatly increased when the addition amount is lowered.
- the recording layer of the optical recording medium according to the first reference example has a reflectance of 6.0% and a transmittance of 65%.
- this is applied to the second recording layer 122 (L1) on the recording light incident side in an optical recording medium having a two-layer structure, and in the case of a three-layer structure, the second or third recording layers 222 and 223 (L1 and Suitable for use in L2).
- the second recording layer 322 (L1) it can be used for other recording layers by changing the composition and thickness.
- a substrate made of a disk-shaped polycarbonate having an outer diameter of 120 mm and a thickness of 1.1 mm was used as the substrate of the optical recording medium, as in the first reference example.
- a dielectric layer was formed.
- a protective layer having a thickness of 100 ⁇ m made of an ultraviolet curable resin was formed thereon as a so-called cover layer on the outermost surface of the recording light incident side.
- Each layer was formed using a target. In 2 O 3 and SnO were used as targets for forming the lower and upper dielectric layers, and ZnO, W, and Pd were used as targets when forming the specific recording layer. In each layer, the composition was adjusted by controlling the sputtering power of each target.
- the gas flow rate during sputtering film formation was Ar: 50 sccm and O 2 : 5 sccm during the formation of the dielectric layer, and Ar: 30 sccm and O 2 : 30 sccm during the formation of the specific recording layer.
- Ar 50 sccm and O 2 : 5 sccm during the formation of the dielectric layer
- Ar 30 sccm and O 2 : 30 sccm during the formation of the specific recording layer.
- the upper and lower In—Sn—O dielectric layers are not provided on the specific recording layer, only the specific recording layer is formed as a single film, and the others are the same as those in the second reference example.
- An optical recording medium was produced.
- FIG. 5 shows the recording characteristics of i-MLSE (evaluation standard for next-generation optical disc) of the optical recording media of the second reference example and the comparative example.
- ⁇ indicates the result of the second reference example
- ⁇ indicates the result of the comparative example.
- the i-MLSE value is also higher than the recording power of the single recording layer of the specific recording layer of the comparative example. It can be seen that the margin has also been greatly improved. Accordingly, even when the specific recording layer is made of ZnWPdO, by providing the dielectric layer containing In, very good characteristics can be obtained, and both the i-MLSE value and the recording power margin can be obtained very well. Yes.
- An optical recording medium having the same structure as that of the second reference example was prepared except that the thickness of the body layer was 10 nm.
- the gas flow rate during sputtering film formation was Ar: 50 sccm and O 2 : 5 sccm during the formation of the dielectric layer, and Ar: 30 sccm and O 2 : 30 sccm during the formation of the specific recording layer.
- the error rate in the specific recording layer was examined using the same evaluation apparatus as in the first reference example.
- the result of the error rate is shown in FIG. FIG. 6 shows that the error rate is sufficiently low and the power margin is very good.
- the specific recording layer was ZnWPdO and the specific recording layer did not contain In, but good results were obtained. Therefore, it can be seen that by providing the In—Sn—O dielectric layer adjacent to the specific recording layer, good recording characteristics can be obtained even if the specific recording layer does not contain In.
- the recording layers of the optical recording media according to the second reference example and the third reference example are also formed on the second recording layer 122 (L1) on the recording light incident side of the optical recording medium having a two-layer structure, for example.
- the second or third recording layers 222 and 223 (L1 and L2) In the case of a four-layer structure, it is preferable to use the second recording layer 322 (L1).
- it can be used for other recording layers by changing the composition and thickness.
- two- to four-layer optical recording media including the above-described specific recording layer were prepared, and the recording characteristics were examined respectively.
- a substrate made of disc-shaped polycarbonate having an outer diameter of 120 mm and a thickness of 1.1 mm was used as the substrate of the optical recording medium.
- An acrylic ultraviolet curable resin was used as the intermediate layer, and an acrylic ultraviolet curable resin was used as the outermost protective layer on the recording light incident side, a so-called cover layer.
- the total thickness from the first recording layer to the protective layer was configured to be 100 ⁇ m, and the total thickness was 1.2 mm.
- These intermediate layer and protective layer were formed by film formation by spin coating and then curing by irradiation with ultraviolet rays. Each example will be described in detail below.
- Example 1 two-layer configuration, see FIG. 1
- the following first recording layer 121 (L0), intermediate layer 14, second recording layer 122 (L1), and protective layer 15 were formed on the substrate 11 having the above-described configuration.
- the material and thickness of each layer are as follows.
- First recording layer L0 lower dielectric layer In—Zn—Sn—O (thickness 5 nm) / recording layer In—Zn—Sn—Pd—O (thickness 40 nm) / upper dielectric layer In—Zn -Sn-O (thickness 5 nm)
- Each layer was formed using a target.
- the gas flow rates were Ar: 70 sccm and O 2 : 30 sccm during the formation of each dielectric layer. Further, when the recording layer was formed, Ar: 70 sccm, O 2 : 30 sccm in the case of L0, Ar: 70 sccm, O 2 : 30 sccm, and N 2 : 10 sccm in the case of L1.
- composition of each layer is expressed as follows in terms of atomic%.
- Zn: Sn 70: 20: 10 (L0 recording layer)
- Zn: Sn: Pd 25: 35: 5: 35 (L1 upper and lower dielectric layers)
- Zn: Sn 70: 20: 10 (L1 recording layer)
- Zn: Sn: Pd 35: 35: 10: 20
- the reflectance of the first recording layer 121 (L0) is 7.7%
- the reflectance of the second recording layer 122 (L1) is 7.5%
- the transmittance is 56%.
- FIG. 7 shows the jitter recording characteristics of this optical recording medium.
- solid lines a1 and a2 indicate the results of the first recording layer 121 and the second recording layer 122, respectively.
- the first and second recording layers 121 and 122 are used as specific recording layers, and dielectric layers 131a, 131b, 132a, and 132b made of In / Al oxide layers are provided above and below them.
- the dielectric layers 131a and 131b and the dielectric layers 132a and 132b are made of the same material. However, different materials and composition ratios can be used in the upper and lower sides, and similarly good recording characteristics can be obtained. It is.
- Example 2 (3-layer configuration, see FIG. 2) The following first recording layer 221 (L0), intermediate layer 241, second recording layer 222 (L1), intermediate layer 242, third recording layer 223 (L2), and protection are formed on the substrate 21 having the above-described configuration.
- Layer 25 was formed.
- the recording layers 221 to 223 are all specified recording layers
- the upper and lower dielectric layers 231a, 231b,... 233a, 233b are all In / Al oxide, in which case In is the main component.
- the dielectric was made of an oxide. The material and thickness of each layer are as follows.
- First recording layer L0 lower dielectric layer In—Sn—O (thickness 10 nm) / recording layer In—Zn—Sn—Al—Pd—O (thickness 40 nm) / upper dielectric layer In—Sn -O (15 nm thickness)
- hird recording layer L2 lower dielectric layer In—Si—Zr—O (thickness 10 nm) / recording layer In—Zn—Sn—Al—Pd—O (thickness 40 nm) / upper dielectric layer In -Si-Zr-O (thickness 30 nm)
- Each layer was formed using a target.
- the gas flow rates were Ar: 70 sccm and O 2 : 30 sccm during the formation of each dielectric layer. Further, when the recording layer was formed, Ar: 70 sccm and O 2 : 30 sccm for L0, Ar: 70 sccm, O 2 : 30 sccm, and N 2 : 10 sccm for L1 and L2.
- composition of each layer is expressed as follows in terms of atomic%.
- Sn 90: 10 (L0 recording layer)
- Zn: Sn: Al: Pd 48: 16: 4: 12: 20 (L1 upper and lower dielectric layers)
- Zn: Ga 86: 7: 7 (L1 recording layer)
- Zn: Sn: Al: Pd 55: 15: 5: 13: 12 (L2 upper and lower dielectric layers)
- Si: Zr 50: 20: 30 (L2 recording layer)
- Zn: Sn: Al: Pd 55: 15: 5: 15: 10
- the third recording layer 223 (L2) has a reflectance of 3.0% and a transmittance of 80%.
- Example 2 On the optical recording medium in Example 2, five continuous tracks were recorded at double speed recording (clock 132 MHz, linear velocity 7.36 m / s) using the same evaluation apparatus as in the reference example and Example 1 described above.
- the i-MLSE evaluation standard for next-generation optical disc
- the recording capacity per layer is about 33.4 GB.
- the i-MLSE values are 9.7% for the first recording layer 221 (L0), 10.0% for the second recording layer 222 (L1), and 10 for the third recording layer 223 (L2).
- FIG. 8 shows the i-MLSE recording characteristics of this optical recording medium.
- solid lines b1 to b3 indicate the results of the first recording layer 221, the second recording layer 222, and the third recording layer 223, respectively.
- the first to third recording layers 221 to 223 are used as specific recording layers, and dielectric layers 231a, 231b,... 233a, 233b made of In / Al oxide layers are provided above and below the specific recording layers.
- the upper and lower dielectric layers 231a and 231b,..., 233a and 233b sandwiching the specific recording layer are made of the same material, but different materials and composition ratios can be used in the upper and lower sides. It is possible to obtain excellent recording characteristics.
- Example 3 (4-layer configuration, see FIG. 3)
- the following first recording layer 321 (L0), intermediate layer 341, second recording layer 322 (L1), intermediate layer 342, and third recording layer 323 (L2) are formed on the substrate 31 having the above-described configuration. did. Further thereon, an intermediate layer 343, a fourth recording layer 324 (L3), and a protective layer 35 were formed.
- the recording layers 321 to 324 are all specified recording layers.
- the upper and lower dielectric layers 331a, 331b,..., 334a, 334b are all made of a dielectric made of In / Al oxide, in this case, an oxide containing In as a main component.
- the material and thickness of each layer are as follows.
- Each layer was formed using a target.
- the gas flow rates were Ar: 70 sccm and O 2 : 30 sccm during the formation of each dielectric layer. Further, when the recording layer was formed, Ar: 70 sccm, O 2 : 30 sccm for L0, Ar: 70 sccm, O 2 : 30 sccm, and N 2 : 10 sccm for L1 to L3.
- each layer is expressed as follows in terms of atomic%.
- Zn: Sn 70: 20: 10 (L0 recording layer)
- Zn: Sn: Pd 25: 35: 5: 35 (L1 upper and lower dielectric layers)
- Zn 80: 20 (L1 recording layer)
- Zn: Sn: Al: Pd 48: 16: 4: 12: 20 (L2 upper and lower dielectric layers)
- Zn: Ga 86: 7: 7 (L2 recording layer)
- Zn: Sn: Al: Pd 55: 15: 5: 13: 12 (L3 upper and lower dielectric layer)
- Zn: Al 50: 10: 40 (L3 recording layer)
- Zn: Sn: Al: Pd 55: 15: 5: 15: 10
- the reflectance of the first recording layer 321 (L0) is 2.5%
- the reflectance of the second recording layer 322 (L1) is 3.3%
- the transmittance is 65%
- the reflectance of the third recording layer 323 (L2) is 3.2%
- the transmittance is 75%
- the reflectance of the fourth recording layer 324 (L3) is 3.6%
- the transmittance is 80%. is there.
- the optical recording medium in the third embodiment in the same evaluation apparatus as in the above-described reference example and the first and second embodiments, first, continuous 5 tracks are recorded at 1 ⁇ speed recording (clock 66 MHz, linear speed 4.92 m / s). Recording was performed and the jitter of the central track was measured. In this case, the recording capacity per layer is about 25 GB. As a result, the jitter bottom value is 5.1% for the first recording layer 321 (L0), 5.1% for the second recording layer 322 (L1), and 4.7% for the third recording layer 323 (L2). %, And the fourth recording layer 324 (L3) had a favorable result of 4.7%.
- FIG. 9 shows jitter recording characteristics of this optical recording medium. In FIG. 9, solid lines c1 to c4 indicate the results of the first recording layer 321 to the fourth recording layer 324, respectively.
- FIG. 10 shows the i-MLSE recording characteristics of this optical recording medium.
- solid lines d1 to d4 indicate the results of the first recording layer 321 to the fourth recording layer 324, respectively.
- FIG. 11 and FIG. 12 show the error rate and the degree of modulation in the fourth recording layer 324 (L3) in this case.
- the first to fourth recording layers 321 to 324 are used as specific recording layers, and dielectric layers 331a, 331b,... 334a, 334b made of In / Al oxide layers are provided above and below the specific recording layers.
- the upper and lower dielectric layers 331a and 331b,..., 334a and 334b sandwiching the specific recording layer are made of the same material, but different materials and composition ratios may be used in the upper and lower sides. Including these examples, good recording characteristics can be obtained in both cases where the recording capacity per layer is about 25 GB and about 32 GB.
- Example 4 (4-layer configuration, modified example of Example 3)
- Example 3 only the first recording layer 321 was not used as a specific recording layer, an optical recording medium was formed using another material, and the recording characteristics were measured.
- the material and thickness of the first recording layer 321 in this example are as follows. A reflective layer made of Ag and having a thickness of 100 nm was formed between the substrate 31 and the first recording layer 321.
- First recording layer L0 lower dielectric layer InSnO (thickness 10 nm) / recording layer ZnS—SiO 2 (thickness 10 nm) / recording layer Sb—ZnS—SiO 2 (thickness 20 nm) / upper dielectric layer InSnO (thickness 20 nm)
- composition ratio of each layer constituting the recording layer is as follows.
- Sn 90: 10
- ZnS: SiO 2 80: 20
- Example 2 with a three-layer structure, the recording capacity per layer is 33.4 GB, and even in the case of Examples 3 and 4 with a four-layer structure, the recording capacity per layer is 32 GB, it is very good. It was found that the recording characteristics can be obtained.
- Example 5 (4-layer configuration) The following first recording layer 321 (L0), intermediate layer 341, second recording layer 322 (L1), intermediate layer 342, and third recording layer 323 (L2) are formed on the substrate 31 having the above-described configuration. did. Further thereon, an intermediate layer 343, a fourth recording layer 324 (L3), and a protective layer 35 were formed.
- the recording layers 321 to 324 are all specified recording layers.
- the upper and lower dielectric layers 331a, 331b,..., 334a, 334b are all composed of a dielectric made of In / Al oxide, in this case, an oxide mainly containing In.
- the material and thickness of each layer are as follows.
- Each layer was formed using a target.
- In 2 O 3 SnO, SiO 2 , and ZrO 2 were used as targets when forming the dielectric layer, and ZnO, W, and Pd were used as targets when forming the specific recording layer.
- the gas flow rates are Ar: 50 sccm and O 2 : 5 sccm when forming the In—Sn—O dielectric layer, and Ar: 50 sccm and O 2 : 1 sccm when forming the In—Si—Zr—O dielectric layer. It was. Further, at the time of forming each recording layer, Ar: 30 sccm and O 2 : 30 sccm.
- composition of each layer is expressed as follows in terms of atomic%.
- Sn 9: 1 (L0 recording layer)
- Pd 60: 40 (L1 upper and lower dielectric layers)
- Sn 9: 1 (L1 recording layer)
- W: Pd 60: 20: 20 (L2 upper and lower dielectric layers)
- Sn 9: 1 (L2 recording layer)
- W: Pd 60: 30: 10 (L3 upper and lower dielectric layers)
- Si: Zr 50: 25: 25 (L3 recording layer)
- Zn: W: Pd 60: 30: 10
- Example 5 For this optical recording medium in Example 5, continuous five tracks were recorded at double speed recording (clock 132 MHz, linear velocity 7.68 m / s) in the same evaluation apparatus as in the above reference example and Examples 1 to 4. Then, i-MLSE of the central track was measured. In this case, the recording capacity per layer is about 32 GB. As a result, the i-MLSE values are 9.5% for the first recording layer 321 (L0), 9.1% for the second recording layer 322 (L1), and 9 for the third recording layer 323 (L2). Good results were obtained with 0.3% and 9.0% with the fourth recording layer 324 (L3).
- FIG. 13 shows the i-MLSE recording characteristics of this optical recording medium. In FIG. 13, solid lines e1 to e4 indicate the results of the first recording layer 321 to the fourth recording layer 324, respectively.
- Example 5 an InSnO layer (ITO layer) or an InSnZrO layer was used as the dielectric layer adjacent to the specific recording layer. These InSnO layers (ITO layers) and InSnZrO layers are also used as dielectric layers adjacent to the specific recording layers in the same manner as the specific recording layer materials of Examples 1 to 4 and other specific recording layer materials. Can be used.
- the optical recording medium of the present invention is not limited to the configuration in each of the above-described embodiments, and even when only one specific recording layer is provided, good recording characteristics can be realized.
- the In / Al oxide layer provided adjacent to the specific recording layer is not limited to the configuration of each of the above-described embodiments, and may be provided only on the upper side or the lower side, or may be made of different materials in the upper and lower sides. Is also possible.
- the In / Al oxide layers provided adjacent to the specific recording layers are the above examples. Contains different compositions.
Abstract
Description
のうち少なくとも1以上の記録層は、PdOと、PdO2とを含む。更に、完全に酸化さ
れた、In、Zn、Al、Sn(すなわちIn2O3、ZnO、Al2O3、SnO2)のうち少なくとも1つを含む組成の特定記録層とする。そして、この特定記録層に隣接して、In又はAlの少なくともいずれかを主成分とするIn/Al酸化物層が設けられる構成とする。
以下、発明を実施するための最良の形態(以下、実施の形態とする)について説明する。
なお、説明は以下の順序で行う。
1.光記録媒体の構成(記録層を2層、3層及び4層構成とする例)
2.参考例(特定記録層のみの単層構成とした光記録媒体の記録特性)
3.実施例(記録層を2層、3層及び4層構成とする例の記録特性)
[光記録媒体の構造]
図1は、本発明の一実施の形態に係る光記録媒体10の概略断面構成図である。図1に示すように、この光記録媒体10は、基板11上に、2層の記録層121(L0)及び122(L1)が形成される。なお、多層記録媒体においては通常、基板に最も近い記録層をL0、次いでL1、L2、・・・とするので、便宜上併記して示す。
は下のいずれか一方に隣接して設けられていてもよい。これらの記録層121及び122のうち、少なくとも一層、好ましくは光入射側の記録層122は、PdOと、PdO2とを含む。更に、完全に酸化された、In、Zn、Al、Sn(すなわちIn2O3、Zn
O、Al2O3、SnO2)のうち少なくとも1つを含む組成の特定記録層とする。また、特定記録層の上下に隣接する誘電体層131a、131b、132a、132bのうち少なくともいずれかは、In又はAlを主成分とするIn/Al酸化物層として構成する。
図2に示す例においては、記録層を3層構成とする光記録媒体20の構成を示す。この例では、基板21上に、図1に示す例と同様にウォブリンググルーブとしての凹凸が形成され、その凹凸形成面の上に、基板21側から順に記録層221(L0)、222(L1)及び223(L2)が、中間層241及び242を介して形成される。図示の例では、記録層221、222及び223の上下に隣接して誘電体層231a及び231b、232a及び232b、233a及び233bがそれぞれ設けられる。そして記録層221~223のうち少なくともいずれか、好ましくは記録層222、223の少なくともいずれかは、上述の組成による特定記録層として構成する。また特定記録層の上下に隣接して設けられる誘電体層のうち少なくともいずれかは、In/Al酸化物層として構成する。記録層223(L2)の上には、保護層25が形成される。図1に示す例と同様に、大容量光ディスク型の構成とする場合は、基板21の外径や厚さ、保護層25の厚さを図1に示す例と同様とすることが好ましい。
基板11(21、31)は、例えばポリカーボネート等の樹脂等の材料より成り、射出成形等によって、マスタリング原盤からトラッキング用のウォブリンググルーブの凹凸形状が転写されて形成される。なお、本発明の光記録媒体においてグルーブ形状は必須ではなく、トラッキングが可能で、且つ記録トラック間クロストークが適切に抑制される構造であればよい。また、記録トラックは光入射側から見てグルーブ上又はランド上とすることができ、記録方式を問わない。
本例において少なくとも1以上の記録層、例えば記録層122、223、324等は、上述したように、PdOと、PdO2とを含むものとする。更に、完全に酸化された、In、Zn、Al、Snのうち少なくとも1つを含む組成の特定記録層として構成する。
特定記録層を含む各記録層121(122、221、・・・等)の成膜は蒸着法やスパッタ法等により行うことができる。例えば特定記録層をスパッタリング法により形成する場合、Pdターゲットと、その他にIn2O3、ZnO、Al2O3、SnOのいずれか1つ以上のターゲットを使用する。または、目的とする組成比の合金ターゲットを用いてもよい。そして、O2ガスに加え、ArガスやN2ガスを流しながら、スパッタ法により成膜する。
まず、特定記録層を含む多層光記録媒体の記録特性を検討する前に、特定記録層単独構成とした光記録媒体の記録特性について、参考例として検討した。
第1の参考例では、光記録媒体の基板として、外径120mm、厚さ1.1mmのディスク状のポリカーボネートより成る基板を用いた。この基板上に、In-Zn-Oより成る厚さ15nmの下層誘電体層、In-Zn-Sn-Al-Pd-Oより成る厚さ40nmの特定記録層、In-Zn-Oより成る厚さ15nmの上層誘電体層を形成した。更にこの上に、記録用光入射側最表面のいわゆるカバー層として、紫外線硬化性樹脂より成る厚さ100μmの保護層を形成した。
また、主に、記録層の組成により、透過率をコントロールすることができる。例えば、Alの添加量を上げるほど透過率は少しずつ高くすることができる。Znは添加量を上げるほど、逆に透過率が少しずつ低くなる。一方、Pdは添加量を上げると透過率は大きく減少し、添加量を下げれば透過率は大きく増大する。
その他、組成や厚さを変えることで、他の記録層に用いることが可能である。
また、スパッタ成膜時のガスの流量は、誘電体層の成膜時はAr:50sccm、O2:5sccm、特定記録層の成膜時はAr:30sccm、O2:30sccmとした。
このようにして、第2の参考例の光記録媒体を作製した。
図5に、第2の参考例及び比較例の光記録媒体のi-MLSE(次世代光ディスク用評価基準)の記録特性を示す。図5中○印は第2の参考例の結果を示し、●印は比較例の結果を示す。
従って、特定記録層をZnWPdOとした場合も、Inを含む誘電体層を設けることにより、非常に良好な特性が得られ、i-MLSE値も記録パワーマージンも非常に良好な結果が得られている。
また、スパッタ成膜時のガスの流量は、誘電体層の成膜時はAr:50sccm、O2:5sccm、特定記録層の成膜時はAr:30sccm、O2:30sccmとした。
図6より、エラーレートが充分低く、パワーマージンも非常に良好な結果が得られた。
したがって、特定記録層に隣接してIn-Sn-O誘電体層を設けていることにより、特定記録層にInを含んでいなくても、良好な記録特性が得られることがわかる。
次に、上述した特定記録層を含む2層~4層の光記録媒体を作製し、その記録特性をそれぞれ検討した。各例共に、光記録媒体の基板としては、外径120mm、厚さ1.1mmのディスク状のポリカーボネートより成る基板を用いた。中間層としてはアクリル系の紫外線硬化性樹脂を用い、また記録用光入射側の最表面の保護層、いわゆるカバー層として、アクリル系の紫外線硬化性樹脂を用いた。第1の記録層から保護層までの全厚さを100μmとなるように構成し、全体として1.2mmの厚さとなるようにした。またこれら中間層及び保護層は、スピンコート法により成膜した後紫外線を照射して硬化することにより形成した。以下各実施例について詳細に説明する。
上述した構成の基板11上に、下記の第1の記録層121(L0)、中間層14、第2の記録層122(L1)、保護層15を形成した。各記録層121及び122の上下に隣接して、In/Al酸化物として、この場合はInを主成分とする酸化物より成る下層の誘電体層131a、132a及び上層の誘電体層131b、132bを設ける構成とした。各層の材料及び厚さは下記の通りである。
(第2の記録層L1):下層誘電体層In-Zn-Sn-O(厚さ10nm)/記録層In-Zn-Sn-Pd-O(厚さ40nm)/上層誘電体層In-Zn-Sn-O(厚さ15nm)
(L0上下誘電体層)In:Zn:Sn=70:20:10
(L0記録層)In:Zn:Sn:Pd=25:35:5:35
(L1上下誘電体層)In:Zn:Sn=70:20:10
(L1記録層)In:Zn:Sn:Pd=35:35:10:20
上述した構成の基板21上に、下記の第1の記録層221(L0)、中間層241、第2の記録層222(L1)、中間層242、第3の記録層223(L2)、保護層25を形成した。この例では、各記録層221~223を全て特定記録層とし、その上下の誘電体層231a、231b、・・・233a、233bを全て、In/Al酸化物、この場合Inを主成分とする酸化物より成る誘電体により構成した。各層の材料及び厚さは下記の通りである。
(第2の記録層L1):下層誘電体層In-Zn-Ga-O(厚さ10nm)/記録層In-Zn-Sn-Al-Pd-O(厚さ40nm)/上層誘電体層In-Zn-Ga-O(厚さ25nm)
(第3の記録層L2):下層誘電体層In-Si-Zr-O(厚さ10nm)/記録層In-Zn-Sn-Al-Pd-O(厚さ40nm)/上層誘電体層In-Si-Zr-O(厚さ30nm)
(L0上下誘電体層)In:Sn=90:10
(L0記録層)In:Zn:Sn:Al:Pd=48:16:4:12:20
(L1上下誘電体層)In:Zn:Ga=86:7:7
(L1記録層)In:Zn:Sn:Al:Pd=55:15:5:13:12
(L2上下誘電体層)In:Si:Zr=50:20:30
(L2記録層)In:Zn:Sn:Al:Pd=55:15:5:15:10
とも可能であり、その場合も同様に良好な記録特性を得ることが可能である。
上述した構成の基板31上に、下記の第1の記録層321(L0)、中間層341、第2の記録層322(L1)、中間層342、第3の記録層323(L2)を形成した。更にその上に、中間層343、第4の記録層324(L3)、保護層35を形成した。この例では、各記録層321~324を全て特定記録層とした。またその上下の誘電体層331a、331b、・・・、334a、334bを全て、In/Al酸化物、この場合Inを主成分とする酸化物より成る誘電体により構成した。各層の材料及び厚さは下記の通り
である。
(第2の記録層L1):下層誘電体層In-Zn-O(厚さ10nm)/記録層In-Zn-Sn-Al-Pd-O膜(厚さ40nm)/上層誘電体層In-Zn-O(厚さ15nm)
(第3の記録層L2):下層誘電体層In-Zn-Ga-O(厚さ10nm)/記録層In-Zn-Sn-Al-Pd-O膜(厚さ40nm)/上層誘電体層In-Zn-Ga-
O(厚さ25nm)
(第4の記録層L3):下層誘電体層In-Zn-Al-O(厚さ10nm)/記録層In-Zn-Sn-Al-Pd-O膜(厚さ40nm)/上層誘電体層In-Zn-Al-O(厚さ30nm)
(L0上下誘電体層)In:Zn:Sn=70:20:10
(L0記録層)In:Zn:Sn:Pd=25:35:5:35
(L1上下誘電体層)In:Zn=80:20
(L1記録層)In:Zn:Sn:Al:Pd=48:16:4:12:20
(L2上下誘電体層)In:Zn:Ga=86:7:7
(L2記録層)In:Zn:Sn:Al:Pd=55:15:5:13:12
(L3上下誘電体層)In:Zn:Al=50:10:40
(L3記録層)In:Zn:Sn:Al:Pd=55:15:5:15:10
実施例3において、第1の記録層321のみを特定記録層とせず、別の材料を用いて光記録媒体を構成し、その記録特性を測定した。この例における第1の記録層321の材料及び厚さは下記の通りである。なお、基板31と第1の記録層321との間にAgより成る厚さ100nmの反射層を形成した。
(In-Sn-O層)In:Sn=90:10
(ZnS-SiO2層)ZnS:SiO2=80:20
(Sb-ZnS-SiO2層)Sb:ZnS-SiO2=4:6
(ただしZnS-SiO2についてはZnS:SiO2=80:20)
特に、3層構成とする実施例2において、一層当たりの記録容量を33.4GB、4層構成とする実施例3及び4において一層当たりの記録容量を32GBとする場合においても、非常に良好な記録特性が得られることが分かった。
上述した構成の基板31上に、下記の第1の記録層321(L0)、中間層341、第2の記録層322(L1)、中間層342、第3の記録層323(L2)を形成した。更にその上に、中間層343、第4の記録層324(L3)、保護層35を形成した。この例では、各記録層321~324を全て特定記録層とした。またその上下の誘電体層331a、331b、・・・、334a、334bを全て、In/Al酸化物、この場合Inを主成分とする酸化物より成る誘電体により構成した。各層の材料及び厚さは下記の通りである。
(第2の記録層L1):下層誘電体層In-Sn-O(厚さ10nm)/記録層Zn-W-Pd-O膜(厚さ30nm)/上層誘電体層In-Sn-O(厚さ15nm)
(第3の記録層L2):下層誘電体層In-Sn-O(厚さ10nm)/記録層Zn-W-Pd-O膜(厚さ30nm)/上層誘電体層In-Sn-O(厚さ22nm)
(第4の記録層L3):下層誘電体層In-Si-Zr-O(厚さ10nm)/記録層Zn-W-Pd-O膜(厚さ30nm)/上層誘電体層In-Si-Zr-O(厚さ30nm)
(L0上下誘電体層)In:Sn=9:1
(L0記録層)Zn:Pd=60:40
(L1上下誘電体層)In:Sn=9:1
(L1記録層)Zn:W:Pd=60:20:20
(L2上下誘電体層)In:Sn=9:1
(L2記録層)Zn:W:Pd=60:30:10
(L3上下誘電体層)In:Si:Zr=50:25:25
(L3記録層)Zn:W:Pd=60:30:10
更に、複数の特定記録層を設けてその上下、又は片側にIn/Al酸化物層を隣接して設ける場合、各特定記録層に隣接して設けるIn/Al酸化物層は、上述の各例においては異なる組成を含んでいる。これに対して、各特定記録層に隣接して設けるIn/Al酸化物層を全て同一の組成とし、膜厚のみを変化させる構成としてもよい。
その他、本発明は上述の例に限定されることなく、本発明構成を逸脱しない範囲で種々の変形、変更が可能である。
Claims (8)
- 基板と、
2層以上4層以下の記録層を有し、
前記記録層のうち少なくとも1以上の記録層は、PdOと、PdO2とを含むと共に、完全に酸化された、In、Zn、Al、Snのうち少なくとも1つを含む組成の特定記録層とされ、
前記特定記録層に隣接して、In及びAlの少なくともいずれかを主成分とするIn/Al酸化物層が設けられる
光記録媒体。 - 前記特定記録層の下層及び上層の両側に隣接して、前記In/Al酸化物層が設けられる請求項1に記載の光記録媒体。
- 前記記録層のうち、記録用光の入射側とは反対側の一層を除いて少なくとも1以上の記録層が、前記特定記録層とされる請求項1に記載の光記録媒体。
- 前記記録層は、記録用光の波長405nm、集光レンズの開口数NA0.85の光学系に対して、一層当たりの記録容量が25GB以上とされる請求項1に記載の光記録媒体。
- 前記記録層が3層以上とされ、
前記記録層は、記録用光の波長405nm、集光レンズの開口数NA0.85の光学系に対して、一層当たりの記録容量が30GB以上とされる請求項1に記載の光記録媒体。 - 前記In/Al酸化物層がInSnO層又はInSiZrO層である請求項1に記載の光記録媒体。
- 前記特定記録層がZn及びWを含み、前記特定記録層に隣接してInを主成分とする酸化物層が設けられる請求項1に記載の光記録媒体。
- 前記特定記録層に隣接する前記Inを主成分とする酸化物層がInSnO層又はInSiZrO層である請求項7に記載の光記録媒体。
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EP11771715.7A EP2562755B1 (en) | 2010-04-19 | 2011-04-06 | Optical recording medium |
US13/640,812 US8685517B2 (en) | 2010-04-19 | 2011-04-06 | Optical recording medium |
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JP6201377B2 (ja) | 2013-04-01 | 2017-09-27 | ソニー株式会社 | 光記録媒体 |
CN105340012B (zh) | 2013-06-28 | 2019-06-28 | 索尼公司 | 光学介质再现装置和光学介质再现方法 |
JP6428619B2 (ja) | 2013-08-14 | 2018-11-28 | ソニー株式会社 | 光媒体再生装置および光媒体再生方法 |
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EP2562755A4 (en) | 2016-07-27 |
US8685517B2 (en) | 2014-04-01 |
KR20130060171A (ko) | 2013-06-07 |
CN102859596B (zh) | 2016-03-16 |
TWI416515B (zh) | 2013-11-21 |
JP2011243270A (ja) | 2011-12-01 |
TW201222544A (en) | 2012-06-01 |
CN102859596A (zh) | 2013-01-02 |
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US20130052389A1 (en) | 2013-02-28 |
EP2562755B1 (en) | 2018-03-28 |
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