JP2010282706A - Pigment for optical information recording medium, and optical information recording medium using the same - Google Patents
Pigment for optical information recording medium, and optical information recording medium using the same Download PDFInfo
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本発明は、光情報記録媒体用色素に関し、より詳しくは、半導体レーザによる波長が360〜450nmのレーザ光(ブルーレーザ光、青紫レーザ光)による記録再生を行う光情報記録媒体用色素及びそれを用いた光情報記録媒体に関する The present invention relates to a dye for optical information recording media. More specifically, the present invention relates to a dye for optical information recording media that performs recording / reproduction with laser light (blue laser light, blue violet laser light) having a wavelength of 360 to 450 nm by a semiconductor laser. The optical information recording medium used
有機色素を記録材料として用いた追記型光記録メディアは、波長780nmのレーザ光を用いて記録再生を行う記録容量650MBあるいは700MBのCD−Rや、波長650nmのレーザ光を用いて記録再生を行う単層ディスクで記録容量4.7GBのDVD−R/+Rが既に広く普及している。これらは未記録での反射率が高く、記録後は反射率が低くなることにより信号として情報を記録するHigh to Low型記録である。 A write-once optical recording medium using an organic dye as a recording material performs recording / reproduction using a CD-R having a recording capacity of 650 MB or 700 MB for recording / reproducing using a laser beam having a wavelength of 780 nm, or a laser beam having a wavelength of 650 nm. Single-layer DVD-R / + R with a recording capacity of 4.7 GB is already widely used. These are high-to-low type recordings in which information is recorded as a signal by having a high reflectivity when not recorded and a low reflectivity after recording.
更なる大容量メディアとして、2006年には波長405nmのレーザで記録再生を行い単層での記録容量が15GBのHD(High−Definition) DVD−Rが商品化された。HD DVD−Rでは、記録極性は、未記録での反射率が低く、記録後は反射率が高くなるLow to Highである。現在開発が進められている有機色素を記録層に用いたBlu−ray Disc−R(以下、「有機BD−R」という。)は、波長405nmのレーザで記録再生を行い単層での記録容量が25GBの追記型光記録メディアである。この有機BD−R記録極性は、HD DVD−Rと同様、Low to Highである。 As a further large-capacity medium, in 2006, a high-definition (HD) DVD-R with a recording capacity of 15 GB in a single layer was recorded and reproduced with a laser having a wavelength of 405 nm. In the HD DVD-R, the recording polarity is Low to High, where the reflectance when not recorded is low and the reflectance becomes high after recording. Blu-ray Disc-R (hereinafter referred to as “Organic BD-R”) using an organic dye as a recording layer, which is currently being developed, performs recording / reproduction with a laser having a wavelength of 405 nm and has a recording capacity of a single layer. Is a 25 GB recordable optical recording medium. The organic BD-R recording polarity is Low to High, similar to HD DVD-R.
こうした、Low to High記録によって高密度の光情報の記録再生が可能な光情報記録媒体に適した新たな有機色素が提案されており、例えば、特許文献1および特許文献2では、特定のアゾ系金属錯体が、Low to High記録の405nmのレーザ光用いた記録再生を行うメディアに好適であるとしている。
また、特許文献3には、450nm以下の短波長のレーザ光によって、Low to High記録を行う光記録媒体において、記録前における記録層の複素屈折率の実部(n)が1.2〜1.5であり、記録した後の記録層の複素屈折率の実部が1.7〜1.9であるものが記載されており、該記録層には、トリメチンオキソノールをアニオンとし、金属錯体をカチオンとする色素化合物が用いられている。
New organic dyes suitable for optical information recording media capable of recording / reproducing high-density optical information by Low to High recording have been proposed. For example, Patent Document 1 and Patent Document 2 disclose specific azo dyes. It is said that the metal complex is suitable for a medium that performs recording and reproduction using a 405 nm laser beam of Low to High recording.
Further, in Patent Document 3, in an optical recording medium that performs Low to High recording with a laser beam having a short wavelength of 450 nm or less, the real part (n) of the complex refractive index of the recording layer before recording is 1.2 to 1. And the real part of the complex refractive index of the recording layer after recording is 1.7 to 1.9, and the recording layer contains trimethine oxonol as an anion, a metal A dye compound having a complex as a cation is used.
有機BD−Rは、厚さ1.1mmで直径120mmの光透過性材料からなる基板上に、反射層、色素含有記録層をこの順に有し、さらに保護層を介して厚さ0.1mmの光透過層(カバー層)を設けた積層構造であり、光透過層(カバー層)側から照射されるレーザ光により記録再生を行うものである。この光透過層は、厚さ0.1mmの光透過性材料からなるシートを接着剤を介して貼り付ける方法か、または紫外線硬化性樹脂等の光透過性の硬化性樹脂をスピンコート法によって厚さ0.1mmに形成する方法によって形成される。
しかしながら、これまでこのような有機BD−Rでは、40%以上の十分に大きな変調度を実現することは非常に困難であった。
その理由は、大容量の記録を行う有機BD−Rは、記録ピットのサイズが従来のCD−RやDVD−R/+Rと比較して極めて微小であることにある。すなわち、記録ピット形成のためのレーザ光のスポットサイズは小さく、かつ記録におけるレーザ光の照射時間が短い。これは記録において照射されるレーザ光のエネルギー量が小さいことを指しており、記録ピットがCD−RやDVD−R/+Rと比べて形成されにくく、記録信号すなわち記録前後の反射率の大きな変化が得られにくいことを意味する。
特許文献1および特許文献2に開示された色素は、こうした大容量の記録を行う、Low to High記録に適したものであり、基本的にはHD DVD−Rと有機BD−Rの両方に使用できる色素であるが、有機BD−R特有の課題については何ら記載されていない。
The organic BD-R has a reflective layer and a dye-containing recording layer in this order on a substrate made of a light transmissive material having a thickness of 1.1 mm and a diameter of 120 mm, and further having a thickness of 0.1 mm via a protective layer. It has a laminated structure in which a light transmission layer (cover layer) is provided, and performs recording and reproduction by laser light irradiated from the light transmission layer (cover layer) side. This light transmissive layer is formed by a method in which a sheet made of a light transmissive material having a thickness of 0.1 mm is attached via an adhesive, or a light transmissive curable resin such as an ultraviolet curable resin is formed by spin coating. It is formed by a method of forming a thickness of 0.1 mm.
However, it has been very difficult to realize a sufficiently large modulation degree of 40% or more with such an organic BD-R.
The reason is that an organic BD-R that performs large-capacity recording has a very small recording pit size compared to conventional CD-R and DVD-R / + R. That is, the spot size of the laser beam for forming the recording pit is small and the irradiation time of the laser beam in recording is short. This indicates that the amount of energy of laser light irradiated in recording is small, and recording pits are hard to be formed compared to CD-R and DVD-R / + R, and the recording signal, that is, a large change in reflectance before and after recording. It is difficult to obtain.
The dyes disclosed in Patent Document 1 and Patent Document 2 are suitable for Low to High recording, which performs such large-capacity recording, and is basically used for both HD DVD-R and organic BD-R. Although it is a pigment that can be produced, it does not describe any problems specific to organic BD-R.
本発明者らが鋭意検討した結果、実際には、記録ピットの部分に光透過層の変形が生じていることがわかってきた。この光透過層の変形と記録層の色素の分解によって、記録ピットと未記録部分との光路長変化を大きくして、大きな変調度を得ることができるものである。ここで、光透過層が厚さ0.1mmの光透過性材料からなるシートを接着剤を介して貼り付ける方法で形成された有機BD−Rでは、接着剤が変形を起こす変形補助層となる。そのため、シート貼り付けによる光透過層を有する有機BD−Rは、特許文献1、特許文献2および特許文献3に記載された有機色素を用いても十分な変調度を実現することが可能である。 As a result of intensive studies by the present inventors, it has been found that the light transmission layer is actually deformed at the recording pit portion. Due to the deformation of the light transmission layer and the decomposition of the dye in the recording layer, the change in the optical path length between the recorded pit and the unrecorded portion can be increased to obtain a large degree of modulation. Here, in the organic BD-R formed by a method in which a light-transmitting layer is formed by attaching a sheet made of a light-transmitting material having a thickness of 0.1 mm via an adhesive, the adhesive becomes a deformation assisting layer that causes deformation. . Therefore, the organic BD-R having a light transmission layer by sticking a sheet can achieve a sufficient degree of modulation even when the organic dyes described in Patent Document 1, Patent Document 2, and Patent Document 3 are used. .
一方、光透過層を硬化性樹脂の塗布によって形成する有機BD−Rでは、光透過層と接して弾性率が低い(25℃での弾性率が40MPa以下)硬化性樹脂の層を形成後、さらに弾性率が高い(25℃での弾性率が40MPa以上)硬化性樹脂を形成し、これらの層の総厚が0.1mmとすることで光透過層(カバー層)を形成することができる(上記特許文献4参照)。これにより弾性率が低い硬化性樹脂の層は変形補助層として機能することにより十分な変調を実現するとともに、弾性率が高い硬化性樹脂の層により傷つきにくい光透過層を形成することができる。しかし、このような変形補助層として機能する弾性率が低い層を導入することによりカバー層の層数が多くなりコスト高となる欠点があることから、弾性率が低い層を有しないことが好ましい。 On the other hand, in the organic BD-R in which the light transmission layer is formed by applying a curable resin, after forming a curable resin layer having a low elastic modulus in contact with the light transmission layer (elastic modulus at 25 ° C. is 40 MPa or less), Furthermore, a light-transmitting layer (cover layer) can be formed by forming a curable resin having a high elastic modulus (elastic modulus at 25 ° C. of 40 MPa or more) and setting the total thickness of these layers to 0.1 mm. (See Patent Document 4 above). Accordingly, the curable resin layer having a low elastic modulus functions as a deformation assisting layer to realize sufficient modulation, and a light-transmitting layer that is hard to be damaged can be formed by the curable resin layer having a high elastic modulus. However, it is preferable not to have a layer having a low elastic modulus because there is a disadvantage that the number of cover layers increases and the cost increases by introducing a layer having a low elastic modulus that functions as a deformation auxiliary layer. .
本発明は、以上のような事情に鑑みてなされたものであって、25℃における弾性率が40MPa以上の硬化性樹脂で形成された光透過層を有する有機BD−Rにおいて、弾性率の低い層がなくても十分に大きな変調度が得られ、良好な記録特性を得ることができる光情報記録媒体用色素及びそれを用いた光情報記録媒体を提供することを目的とする。 The present invention has been made in view of the above circumstances, and in an organic BD-R having a light transmission layer formed of a curable resin having an elastic modulus at 25 ° C. of 40 MPa or more, the elastic modulus is low. An object of the present invention is to provide a dye for an optical information recording medium capable of obtaining a sufficiently large degree of modulation without a layer and obtaining good recording characteristics, and an optical information recording medium using the same.
本発明者らは、上記目的を達成すべく鋭意研究を重ねた結果、有機色素を含む記録層が、吸収スペクトルのピーク波長λmaxが370〜425nmでかつ複素屈折率の実部nが1.65以上であること、より好ましくは1.70〜2.10のときに、この色素層を含むIn−Groove記録でかつLow to High型記録の有機BD−Rで変調度が40%以上となることを見出した。 As a result of intensive studies to achieve the above object, the present inventors have found that a recording layer containing an organic dye has a peak wavelength λmax of an absorption spectrum of 370 to 425 nm and a real part n of a complex refractive index of 1.65. More preferably, when the ratio is 1.70 to 2.10, the modulation degree is 40% or more in an organic BD-R of In-Groove recording including this dye layer and Low to High recording. I found.
本発明は、これらの知見に基づいて完成に至ったものであり、以下のとおりのものである。
[1]基板の一方の主面上に、少なくとも、光反射層と、有機色素を含有する光記録層と、保護層と、25℃における弾性率が40MPa以上の硬化性樹脂で形成された光透過層と、がこの順に形成された光情報記録媒体において、前記光記録層は、レーザ光により記録した後の反射率が記録する前の反射率よりも高くなる光学特性を有し、吸収スペクトルのピーク波長λmaxが370〜425nmであり、かつ記録前の複素屈折率の実部(n)が1.65以上であることを特徴とする光情報記録媒体。
[2]前記光記録層は、記録前の複素屈折率の実部(n)が1.70〜2.10であることを特徴とする前記[1]の光情報記録媒体。
The present invention has been completed based on these findings, and is as follows.
[1] Light formed on one main surface of the substrate with at least a light reflection layer, an optical recording layer containing an organic dye, a protective layer, and a curable resin having an elastic modulus at 25 ° C. of 40 MPa or more. In the optical information recording medium in which the transmission layer is formed in this order, the optical recording layer has an optical characteristic that the reflectance after recording with laser light is higher than the reflectance before recording, and the absorption spectrum An optical information recording medium having a peak wavelength λmax of 370 to 425 nm and a real part (n) of a complex refractive index before recording of 1.65 or more.
[2] The optical information recording medium according to [1], wherein the optical recording layer has a real part (n) of a complex refractive index before recording of 1.70 to 2.10.
本発明によれば、有機BD−Rのような短波長レーザ(405nm)で記録再生を行う光記録メディアにおいて、記録感度が高く、光透過層に弾性率の低い層を設けなくても40%以上という大きな変調度が得られ、良好な記録特性を得ることができる。 According to the present invention, in an optical recording medium in which recording / reproduction is performed with a short wavelength laser (405 nm) such as an organic BD-R, the recording sensitivity is high and even if a layer having a low elastic modulus is not provided in the light transmission layer, 40% A large modulation degree as described above can be obtained, and good recording characteristics can be obtained.
以下、図面により、本発明の実施の形態にかかる光情報記録媒体、及びその記録層に用いる光情報記録媒体用色素について説明する。
図1は、本発明のブルーレーザ光を用いる光情報記録媒体の一つの実施形態を模式的に示す断面図である。図1に示すとおり、本発明の光情報記録媒体11は、基板2と、この基板2上に形成した光反射層3と、この光反射層3の上に形成した光吸収層すなわち光記録層4と、この光記録層4の上に形成した保護層5と、この保護層5の上に形成されたカバー層すなわち光透過層6とを有するものである。
Hereinafter, the optical information recording medium according to the embodiment of the present invention and the dye for the optical information recording medium used for the recording layer will be described with reference to the drawings.
FIG. 1 is a cross-sectional view schematically showing one embodiment of an optical information recording medium using the blue laser beam of the present invention. As shown in FIG. 1, an optical information recording medium 11 of the present invention includes a substrate 2, a light reflecting layer 3 formed on the substrate 2, and a light absorbing layer, that is, an optical recording layer, formed on the light reflecting layer 3. 4, a protective layer 5 formed on the optical recording layer 4, and a cover layer, that is, a light transmission layer 6 formed on the protective layer 5.
上記構成の光情報記録媒体の記録は、光透過層6を通してレーザ光7を照射することにより行われるが、記録においては、光記録層に含まれる色素が記録光(レーザ光)を吸収し、光エネルギーを熱エネルギーに変換する、すなわち熱を生じ、その熱により色素が熱分解することにより色素の光学的物性が変化する。この光記録層の光学物性の変化により記録でのレーザ光の照射部分、すなわち記録部分の反射率が変化することで記録が行われる。 Recording of the optical information recording medium having the above configuration is performed by irradiating the laser beam 7 through the light transmission layer 6, but in recording, the dye contained in the optical recording layer absorbs the recording light (laser light), The optical physical properties of the dye are changed by converting light energy into heat energy, that is, heat is generated and the dye is thermally decomposed by the heat. Recording is performed by changing the reflectance of the portion irradiated with laser light in recording, that is, the recording portion, due to the change in the optical physical properties of the optical recording layer.
本発明では、記録感度が高く、具体的には2倍速記録での記録パワーが7mW以下において、変調度が40%以上とするための光記録層の光学物性の最適値を見出した。
記録後の反射率が大きくなるLow to High型の記録特性を有する光情報記録媒体では、未記録時の反射率をできるだけ小さくした方が、記録前後の反射率の変化である変調度を大きく取ることができる。記録層の膜厚が一定である場合、未記録時の記録層の複素屈折率の実部nが大きいほど未記録時の反射率は小さくなる。そしてレーザ光の照射部分すなわち記録部分はnの値が小さくなって反射率が大きくなる。そのため、できるだけnの値を大きくすることが好ましい。また、吸収スペクトルのピーク波長λmaxを370〜425nmとすることにより、405nmにおける光吸収を大きくすることができる。これにより、未記録時の反射率をより小さくすることができる。
なお、変調度は、8Tピットの反射率Rにより以下の式で定義される。
変調度=(R8T_top−R8T_bottom)/R8T_top
図2は、その説明図である。上記の式から、R8T_bottomすなわち未記録時の反射率を小さくすると、R8T_top−R8T_bottomの値が大きくなるため、変調度は大きくなる。なお、R8T_bottomの値が小さくなるとともにR8T_topの値も小さくなることがあるが、この場合、上記の式の分母が小さくなるので、変調度は大きくなる。
In the present invention, the optimum value of the optical properties of the optical recording layer was found to achieve high recording sensitivity, specifically, when the recording power in double speed recording is 7 mW or less and the degree of modulation is 40% or more.
In an optical information recording medium having a Low to High recording characteristic in which the reflectance after recording is increased, the modulation degree, which is a change in reflectance before and after recording, is increased by reducing the reflectance when not recorded as much as possible. be able to. When the film thickness of the recording layer is constant, the greater the real part n of the complex refractive index of the recording layer at the time of non-recording, the smaller the reflectance at the time of unrecording. Then, the laser beam irradiated portion, that is, the recording portion has a smaller n value and a higher reflectance. Therefore, it is preferable to increase the value of n as much as possible. Further, by setting the peak wavelength λmax of the absorption spectrum to 370 to 425 nm, light absorption at 405 nm can be increased. Thereby, the reflectance at the time of non-recording can be made smaller.
The degree of modulation is defined by the following equation based on the reflectance R of 8T pits.
Modulation degree = (R 8T_top −R 8T_bottom ) / R 8T_top
FIG. 2 is an explanatory diagram thereof. From the above equation, when R 8T_bottom, that is, the reflectance during unrecording is reduced, the value of R 8T_top −R 8T_bottom increases, and the modulation degree increases. Note that the value of R 8T_bottom may decrease and the value of R 8T_top may also decrease. However, in this case, the denominator of the above equation is decreased, and thus the degree of modulation increases.
以下、本発明における、記録層の複素屈折率の実部nの数値を適切な値とする方法について説明する。
図3は、後述する本発明の実施例1で用いた(色素1)の薄膜の複素屈折率の実部nと虚部kのスペクトル形状を示す。該図では、nのスペクトルは、340nm付近で極小値を有し、420nm付近で極大値を有する。一方、kのスペクトルは、385nm付近に最大値を有し、nの極大波長と極小波長との中間付近にkが最大となる波長を有する。このようなnおよびkのスペクトル形状は理論的な説明が行われている(例えば、「光物性入門」 著者:小林浩一、出版社:裳華房)
Hereinafter, a method of setting the numerical value of the real part n of the complex refractive index of the recording layer to an appropriate value in the present invention will be described.
FIG. 3 shows the spectrum shapes of the real part n and the imaginary part k of the complex refractive index of the thin film of (Dye 1) used in Example 1 of the present invention described later. In the figure, the spectrum of n has a minimum value near 340 nm and a maximum value near 420 nm. On the other hand, the spectrum of k has a maximum value in the vicinity of 385 nm, and has a wavelength in which k is maximum in the vicinity of the middle between the maximum wavelength and the minimum wavelength of n. Such spectral shapes of n and k have been theoretically explained (for example, "Introduction to optical properties" Author: Koichi Kobayashi, Publisher: Kankabo)
図4は、(色素1)の吸収スペクトルを示す図である。
kは消衰係数であることから、kが最大となる波長およびkのスペクトル形状は、吸収スペクトルと対応する。nのスペクトルのピーク波長が約420nm付近であることから、吸収スペクトルの吸収ピークの波長λmaxが長波長化すると、nは減少する。一方、λmaxが短波長化すると、nのピーク波長がレーザ光の波長405nmよりも長短波長であるときにはnは増加していき、nのピーク波長が405nmにおいてnは最大となり、さらにnのピーク波長がより長波長になると減少していく。
このように吸収スペクトルのλmaxを適切な範囲に設定することにより、nを適切な数値とすることができる。
FIG. 4 is a diagram showing an absorption spectrum of (Dye 1).
Since k is an extinction coefficient, the wavelength at which k is maximum and the spectral shape of k correspond to the absorption spectrum. Since the peak wavelength of the spectrum of n is about 420 nm, n decreases when the wavelength λmax of the absorption peak of the absorption spectrum is increased. On the other hand, when λmax is shortened, n increases when the peak wavelength of n is longer or shorter than the wavelength 405 nm of the laser beam, and becomes maximum when the peak wavelength of n is 405 nm, and further, the peak wavelength of n Decreases at longer wavelengths.
Thus, by setting λmax of the absorption spectrum to an appropriate range, n can be set to an appropriate numerical value.
本発明において、光記録層4は複素屈折率の実数部nが1.65以上、より好ましくは1.70〜2.10である色素膜により構成されている。色素膜は単一の種類の色素あるいは複数の種類の色素の混合により形成されていても良い。 In the present invention, the optical recording layer 4 is composed of a dye film having a real part n of a complex refractive index of 1.65 or more, more preferably 1.70 to 2.10. The dye film may be formed by a single kind of dye or a mixture of plural kinds of dyes.
本発明の光記録層4を構成する色素としては、例えば下記の一般式(I)ないし(IV)に示す構造のアゾ化合物に金属イオンが配位する金属錯体化合物、または下記一般式(V)に示す構造のシアニン化合物であって、吸収スペクトルのピーク波長λmaxが370〜425nmであり、複素屈折率の実数部nが1.65以上、より好ましくは1.70〜2.10である色素が好ましく用いられる。なお、下記一般式(I)及び(II)に示す特定の構造のアゾ化合物に配位する金属イオンは、ニッケル、コバルト、銅から選ばれる。 Examples of the dye constituting the optical recording layer 4 of the present invention include a metal complex compound in which a metal ion is coordinated to an azo compound having a structure represented by the following general formulas (I) to (IV), or the following general formula (V). A dye having a peak wavelength λmax of absorption spectrum of 370 to 425 nm and a real part n of a complex refractive index of 1.65 or more, more preferably 1.70 to 2.10. Preferably used. In addition, the metal ion coordinated to the azo compound of the specific structure shown to the following general formula (I) and (II) is chosen from nickel, cobalt, and copper.
環Aは例えば、以下の(化3)に示すものが挙げられるが限定されるものではない。
Examples of ring A include, but are not limited to, those shown in the following (Chemical Formula 3).
環Bは例えば、以下の(化6)に示すものから選ばれる。
Ring B is selected from, for example, those shown in the following (Chemical Formula 6).
光記録層4は、これらの色素を例えば2,2,3,3−テトラフルオロ−1−プロパノール(TFP)溶液に溶かした色素溶液を、DCジッタ値が最も低くなるときの光学密度(Optical Density:以下OD値と略す)になるように、スピンコート法によって塗布して形成される。ここでOD値とは、色素の最大吸収波長における吸光度を示すものである。測定方法は、図1の基板2の上に、直接記録層5を塗布して、各々の色素の最大吸収波長の光を用いて吸光度を測定することで行われる。OD値は成膜条件(回転数、時間等)によって調整される。DCジッタが最も低くなるOD値は、記録層5の成膜条件を変えてOD値を変えたサンプルディスクを複数点用意し、市販の記録再生装置(例えばパルステック社製 ODU−1000)で記録を行い、それぞれのDCジッタ値を求め、その結果から決定する。 The optical recording layer 4 has an optical density (Optical Density) at which the DC jitter value is lowest when a dye solution in which these dyes are dissolved in a 2,2,3,3-tetrafluoro-1-propanol (TFP) solution, for example. : Hereinafter abbreviated as OD value) and formed by applying by spin coating method. Here, the OD value indicates the absorbance at the maximum absorption wavelength of the dye. The measuring method is performed by applying the recording layer 5 directly on the substrate 2 of FIG. 1 and measuring the absorbance using light of the maximum absorption wavelength of each dye. The OD value is adjusted according to the film forming conditions (rotation speed, time, etc.). The OD value with the lowest DC jitter is recorded with a commercially available recording / reproducing apparatus (for example, ODU-1000 manufactured by Pulstec) by preparing multiple sample disks with different OD values by changing the film formation conditions of the recording layer 5. To determine each DC jitter value and determine from the result.
光記録層4の未記録時の屈折率n(複素屈折率の実部)と未記録時の消衰係数k(複素屈折率の虚部)は、ポリカーボネート製の両面が平坦な基板の上面に、色素をTFPに溶解し20g/Lの濃度に調製した色素溶液をスピンコート法により塗布し、温度80℃で30分乾燥後、膜厚40nmである色素薄膜を形成し、n、k計測装置(STEAG ETA−Optik GmbH社製ETA−RT/UV)で測定することにより得られる。 The optical recording layer 4 has an unrecorded refractive index n (real part of the complex refractive index) and an unrecorded extinction coefficient k (imaginary part of the complex refractive index) on the upper surface of the substrate made of polycarbonate and flat. The dye solution prepared by dissolving the dye in TFP to a concentration of 20 g / L is applied by spin coating, dried at a temperature of 80 ° C. for 30 minutes, and then a dye thin film having a film thickness of 40 nm is formed. It is obtained by measuring with (STEAG ETA-Optik GmbH ETA-RT / UV).
以下、本発明の光情報記録媒体11における、前記光記録層4以外の構成層について説明する。
(基板)
基板2は、レーザ光に対する屈折率がたとえば1.5〜1.7程度の範囲内の透明度の高い材料で、耐衝撃性に優れた主として樹脂により形成したもの、たとえばポリカーボネート、ガラス板、アクリル板、エポキシ板等を用いる。
基板2には、ピッチ0.32μmからなるスパイラル状の案内溝が形成される。トラッキングの誘導をするソフト等の変更を伴えば、溝はリング状の溝でも使用が可能となる。この案内溝は溝幅W1が160nm〜200nm、溝深さD1が32nm〜45nmが好ましい。ここで溝幅W1は、図1に示すように、溝深さD1の半分の深さの位置での幅すなわち半値幅で測定される。この案内溝上に反射膜3が構成される。
Hereinafter, constituent layers other than the optical recording layer 4 in the optical information recording medium 11 of the present invention will be described.
(substrate)
The substrate 2 is a highly transparent material having a refractive index with respect to laser light in the range of, for example, about 1.5 to 1.7, and is mainly formed of a resin excellent in impact resistance, such as polycarbonate, glass plate, acrylic plate, etc. An epoxy board is used.
A spiral guide groove having a pitch of 0.32 μm is formed on the substrate 2. The groove can be used as a ring-shaped groove if the software for guiding the tracking is changed. The guide groove preferably has a groove width W1 of 160 nm to 200 nm and a groove depth D1 of 32 nm to 45 nm. Here, as shown in FIG. 1, the groove width W1 is measured by a width at a half depth of the groove depth D1, that is, a half width. A reflective film 3 is formed on the guide groove.
(光反射層)
光反射層3は、熱伝導率および光反射性の高い金属膜であり、たとえば、金、銀、銅、アルミニウム、あるいはこれらを含む合金を、蒸着法、スパッタ法等の手段により形成する。
反射膜3の厚さは40nm〜65nmが好ましい。なお、反射膜3は案内溝内にも形成されるため、案内溝の寸法は反射膜の厚さ分変化する。反射膜を形成後の溝3’は、溝幅W2が150nm〜190nm、溝深さD2は32nm〜45nmが好ましい。
(Light reflecting layer)
The light reflecting layer 3 is a metal film having a high thermal conductivity and high light reflectivity. For example, gold, silver, copper, aluminum, or an alloy containing these is formed by means such as vapor deposition or sputtering.
The thickness of the reflective film 3 is preferably 40 nm to 65 nm. Since the reflective film 3 is also formed in the guide groove, the size of the guide groove changes by the thickness of the reflective film. The groove 3 ′ after forming the reflective film preferably has a groove width W2 of 150 nm to 190 nm and a groove depth D2 of 32 nm to 45 nm.
(保護層)
保護層5は、カバー層6の成膜時における記録層4に含まれる色素のカバー層6への拡散や、カバー層6の形成用の硬化樹脂の溶剤等の記録層4への浸透などの混和現象を防止するためのものである。この保護層5を構成する材料は、酸化珪素、特に二酸化珪素や、酸化亜鉛、酸化セリウム、酸化イットリウム等の酸化物;硫化亜鉛、硫化イットリウムなどの硫化物;窒化珪素などの窒化物、炭化珪素;酸化物と硫黄化合物との混合物などが挙げられる。この保護層6はスパッタリング等の方法で形成される。
(Protective layer)
The protective layer 5 is formed by, for example, diffusing the dye contained in the recording layer 4 when the cover layer 6 is formed into the cover layer 6 or penetrating the recording layer 4 with a solvent of a cured resin for forming the cover layer 6. This is to prevent the mixing phenomenon. The material constituting the protective layer 5 is silicon oxide, particularly silicon dioxide, oxides such as zinc oxide, cerium oxide, yttrium oxide; sulfides such as zinc sulfide and yttrium sulfide; nitrides such as silicon nitride; silicon carbide A mixture of an oxide and a sulfur compound. The protective layer 6 is formed by a method such as sputtering.
(光透過層)
本発明の光情報記録媒体11においては、光透過層6を通してレーザ光7を照射し、光記録層4が照射されたレーザ光を吸収して光エネルギーを熱エネルギーに変換し、光記録層4の分解あるいは変性などを生じさせ、記録ピットを形成し、記録部分および未記録部分の光反射率などによるコントラストを電気信号(変調度)として読み取っている。
したがって、光透過層6は、レーザ光を透過する材料、例えばアクリル系樹脂,ポリオレフィン系樹脂等の硬化性樹脂で形成されている。
また、光透過層6は、光反射層3や光記録層4を外部の衝撃から保護するとともに、これら各層3,4が湿気等の腐食因子と接触するのを防止する保護層としても機能する。
この光透過層6は、紫外線または放射線によって硬化する硬化性樹脂をスピンコート法等によって厚さ0.1mmに形成される。この光透過層6の光透過性は、硬化後の厚み0.1mmで、405nmの波長の光にて分光光度計で測定したときに70%以上好ましくは80%以上である。また、この光透過層6は、25℃における弾性率が40MPa以上である。ここで、25℃における弾性率は、ナノインデンテーション法(神戸製鋼技報/Vol.52 No.2(Sep.2002)P74〜P77)によって測定される。
(Light transmission layer)
In the optical information recording medium 11 of the present invention, the laser beam 7 is irradiated through the light transmission layer 6, the laser beam irradiated by the optical recording layer 4 is absorbed, and the light energy is converted into thermal energy. The recording pits are formed, and the contrast due to the light reflectance of the recorded portion and the unrecorded portion is read as an electric signal (degree of modulation).
Therefore, the light transmission layer 6 is formed of a material that transmits laser light, for example, a curable resin such as an acrylic resin or a polyolefin resin.
Further, the light transmission layer 6 protects the light reflection layer 3 and the optical recording layer 4 from external impacts, and also functions as a protection layer for preventing the layers 3 and 4 from coming into contact with corrosion factors such as moisture. .
This light transmission layer 6 is formed of a curable resin that is cured by ultraviolet rays or radiation to a thickness of 0.1 mm by spin coating or the like. The light transmittance of the light transmission layer 6 is 70% or more, preferably 80% or more when measured with a spectrophotometer with a light having a wavelength of 405 nm and a thickness of 0.1 mm after curing. The light transmission layer 6 has an elastic modulus at 25 ° C. of 40 MPa or more. Here, the elastic modulus at 25 ° C. is measured by a nanoindentation method (Kobe Steel Engineering Reports / Vol. 52 No. 2 (Sep. 2002) P74 to P77).
以下、本発明を実施例によってさらに具体的に説明するが、本発明はこれら実施例により何ら限定されるものではない。
(実施例1)
中心部分に貫通孔を有し、かつトラックピッチ0.32μm、溝幅180nm、溝深さ32nmの案内溝を有する外径120mm、厚さ1.1mmの円板状のポリカーボネート製の基板を、射出成形によって作成した。この基板の案内溝が形成された面にAg合金をスパッタリングして60nmの厚さの反射層を形成した。その後、下記の(化8)に示す化学式で表される有機色素(色素1:n=1.85)をTFP溶剤に溶かした色素溶液をスピンコート法により塗布し、温度80℃で10分乾燥後、吸収最大波長(λmax=379nm)でのOD値が0.25となるように光吸収層すなわち光記録層4を形成した。その後、更に光記録層3の上面にZnS−SiO2材料からなる透明な保護層5を20nmの厚さになるようにスパッタリングした。それからUV硬化樹脂をスピンコート法により塗布し、UV光照射により硬化させることにより厚さ0.1mmのカバー層すなわち光透過層6を形成し、有機BD−R11の追記型の光情報記録媒体の試料を得た。なお、光透過層6の弾性率は、ナノインデンテーション法により試験荷重0.1mNで25℃の室温下で弾性率を求めたところ、40MPa以上であった。
EXAMPLES Hereinafter, the present invention will be described more specifically with reference to examples, but the present invention is not limited to these examples.
Example 1
A disc-shaped polycarbonate substrate having an outer diameter of 120 mm and a thickness of 1.1 mm having a through hole in the central portion and a guide groove having a track pitch of 0.32 μm, a groove width of 180 nm, and a groove depth of 32 nm is injected. Created by molding. A reflective layer having a thickness of 60 nm was formed by sputtering an Ag alloy on the surface of the substrate on which the guide grooves were formed. Thereafter, a dye solution in which an organic dye represented by the chemical formula shown below (Chemical Formula 8) (Dye 1: n = 1.85) is dissolved in a TFP solvent is applied by spin coating, and dried at a temperature of 80 ° C. for 10 minutes. Thereafter, the light absorption layer, that is, the optical recording layer 4 was formed so that the OD value at the maximum absorption wavelength (λmax = 379 nm) was 0.25. Thereafter, a transparent protective layer 5 made of a ZnS—SiO 2 material was further sputtered on the upper surface of the optical recording layer 3 to a thickness of 20 nm. Then, a UV curable resin is applied by a spin coating method and cured by UV light irradiation to form a cover layer having a thickness of 0.1 mm, that is, a light transmission layer 6, and an organic BD-R11 write-once type optical information recording medium. A sample was obtained. The elastic modulus of the light transmission layer 6 was 40 MPa or more when the elastic modulus was obtained at room temperature of 25 ° C. with a test load of 0.1 mN by the nanoindentation method.
続いて、この有機BD−R11を開口数NA0.85、レーザ波長405nmの市販の記録再生装置(パルステック社製ODU−1000)を用いて、線速9.84m/秒(2倍速記録)で記録し、再生特性を評価したところ、DCジッタが最も小さくなるレーザパワーすなわち最適レーザパワーは4.7mWであった。
その後、上記記録機を用いて、レーザ出力を0.35mWにし、記録信号を再生したところ、このときの変調度は45%であり、記録感度が高く、変調度が大きいという良好な記録特性が得られた。
表1に光透過層6の25℃での弾性率、最大吸収波長(λmax)、n、k、OD値、記録パワー、変調度を測定した結果を示す。
Subsequently, the organic BD-R11 was recorded at a linear velocity of 9.84 m / sec (double speed recording) using a commercially available recording / reproducing apparatus (ODU-1000 manufactured by Pulstec Corp.) having a numerical aperture NA of 0.85 and a laser wavelength of 405 nm. When recording and reproducing characteristics were evaluated, the laser power at which the DC jitter was minimized, that is, the optimum laser power was 4.7 mW.
After that, when the laser output was set to 0.35 mW and the recording signal was reproduced using the above-mentioned recorder, the modulation degree at this time was 45%, the recording sensitivity was high, and the good recording characteristics that the modulation degree was large were obtained. Obtained.
Table 1 shows the measurement results of the elastic modulus at 25 ° C., the maximum absorption wavelength (λ max ), n, k, OD value, recording power, and modulation degree of the light transmission layer 6.
(実施例2〜11)
実施例1において、(色素1)の代わりに、それぞれλmaxが425nm以下、n=1.70以上である下記の(化8)〜(化18)に示す化学式で表される色素2〜11を用いたこと、および光透過層6として弾性率の異なる硬化性樹脂を用いたこと以外は、実施例1と同様にして有機BD−R 11を得た。
実施例1と同様にして測定した結果は表1の実施例2〜11のそれぞれの欄に示した通り、いずれも変調度40%以上が得られた。
(Examples 2 to 11)
In Example 1, in place of (Dye 1), λ max is 425 nm or less and n = 1.70 or more, respectively, and Dyes 2 to 11 represented by chemical formulas shown in the following (Chemical Formula 8) to (Chemical Formula 18) Organic BD-R 11 was obtained in the same manner as in Example 1 except that a curable resin having a different elastic modulus was used as the light transmission layer 6.
The results measured in the same manner as in Example 1 showed that the degree of modulation was 40% or more as shown in the respective columns of Examples 2 to 11 in Table 1.
(比較例1〜5)
実施例1において、色素1の代わりに、それぞれλmaxが426nm以上、n=1.70未満である下記の比較色素1〜6を用いたこと以外は同様にして有機BD−R 11を得た。なお、硬化性樹脂は、それぞれ実施例1、実施例5、実施例4、実施例6、実施例4、実施例1と同じ硬化性樹脂を用いた。実施例1と同様にして測定した結果は表1の比較例1〜6のそれぞれの欄に示した通り、いずれも変調度40%未満であった。
(Comparative Examples 1-5)
In Example 1, organic BD-R 11 was obtained in the same manner except that the following comparative dyes 1 to 6 having λ max of 426 nm or more and n = 1.70 were used instead of the dye 1 respectively. . In addition, the curable resin same as Example 1, Example 5, Example 4, Example 6, Example 4, Example 4, and Example 1 was used for the curable resin, respectively. The results measured in the same manner as in Example 1 were all less than 40% in modulation degree as shown in the respective columns of Comparative Examples 1 to 6 in Table 1.
本発明の光情報記録媒体用色素は、ブルーレーザにより、In−Groove記録でかつLow to High型記録を行う光記録メディアにおいて使用することができる。 The dye for optical information recording media of the present invention can be used in optical recording media that perform In-Groove recording and Low to High recording with a blue laser.
2:基板
3:光反射層
4:光記録層(光吸収層)
5:保護層
6:光透過層(カバー層)
7:レーザ光(記録、再生)
11:本発明の追記型光ディスク(有機BD―R)
2: Substrate 3: Light reflection layer 4: Optical recording layer (light absorption layer)
5: Protective layer 6: Light transmission layer (cover layer)
7: Laser light (recording, reproduction)
11: Write-once optical disc of the present invention (organic BD-R)
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