Title of Invention

OPTICAL RECORDING MEDIUM, OPTICAL RECORDING MATERIAL AND METAL COMPLEX COMPOUND

Abstract An optical recording medium is disclosed. The medium comprises: a substrate; and a recording layer which is provided on the substrate directly or on other layers provided on the substrate, having a capability of recording and/or reading information by irradiating a laser light thereon, the laser light having a wavelength of from 350 nm to 530 nm, wherein the recording layer contains a metal complex compound comprising an azo compound having a coupler component with a cyclic β-diketone structure and a diazo component with a nitrogen-containing hererocyclic aromatic ring structure, and a divalent metal ion coordinated by the azocompound, and wherein the coupler component has any one of the structures selected from Meldrum's acid, tetronic acid, barbituric acid, thiobarbituric acid, hydroxycoumarin, hydroxycarbostyril, pyrazolidinedione, indandione, cyclohexanedione, and diketopyrimidine.
Full Text

DESCRIPTION
Technical Field
[0001]
The present invention relates to an optical recording medium and
others, and more specifically, to an optical recording medium and others
applicable to blue laser, having an excellent light resistance.
Background Art
[0002]
Presently, various kinds of optical recording media including
CD-R/RW, DVD-R/RW, MO and others have been widely accepted and used
as external memory devices for information processing machines such as
computers because a large quantity of information may be stored and
randomly accessed easily as in DVD-RAM. Among the optical recording
media, recordable optical recording media such as CD-R and DVD-R, which
are organic dye type optical recording media having a recording layer
containing organic dye compounds, have been considered to have
advantages from the viewpoint of low cost and easy production.
Generally, the optical recording media such as CD-R and DVD-R that
are available in the market are designed as, for example, in the case of
CD-R, being suitable for recording and reading information with a laser light
of about 780 nm wavelength, or in the case of DVD-R, being suitable for
recording and reading information with a laser light of 600 nm to 700 nm
wavelength. As a dye used for recording in CD-R or DVD-R, for example,

an azo compound is used (refer to Patent Document 1, Patent Document 2,
and Patent Document 3).
[0003]
Patent Document 1: International Publication No. WO 91/018950,
Patent Document 2: Japanese Patent Application Laid-Open
Publication No. H09-277703, and
Patent Document 3: Japanese Patent Application Laid-Open ,..
Publication No. 2001-271001.
Disclosure of the Invention
Problems to be Solved by the Invention
[0004]
Meanwhile, due to the increase in information quantity handled, the
recording density of the media has been requested to be increased. In
particular, in recent years, by using a laser light with a short oscillation
wavelength such as a blue laser that has been developed intensively, an
optical recording medium having a capability of recording and reading
information at a high density has been proposed.
In view of such request, when conventional optical recording media
that optically record and read information using a laser light with a
relatively long wavelength are applied to recording and reading information
using a laser light with a shorter wavelength, the reflectance is lowered and
recording or reading is not performed adequately.
[0005]
For example, in the optical recording medium described in the
aforementioned Patent Document 1, an azo compound having a coupler
component with an N,N-dialkylaniline structure is used as a dye for
recording. With the N,N-dialkylaniline structure, a dye having an

extremely large molar absorption coefficient is likely to be obtained.
However, in an absorption spectrum in a solution of an azo metal chelate
compound that is a complex between the foregoing azo compound and a
metal, Amax is observed at 500 nm or longer. Thereby, in an absorption
spectrum of a coating film that contains the dye of the foregoing
metal-containing azo complex compound, almost no absorption is observed
at around 405 nm wavelength of laser light. The problem is that the
coating film is likely to have poor sensitivity to blue laser light.
[0006]
Further, in the optical recording medium described in Patent
Document 2, an azo compound having a coupler component with a pyridone
structure is used as a dye for recording. The absorption spectrum of the
azo compound has been known to exhibit Amax at a shorter wavelength, but
the absorption spectrum of a metal chelate compound composed of a metal
and an azo compound having a benzothiazole or thiazole structure as the
diazo component has small absorption at around the laser light wavelength
of 405 nm.
[0007]
Further, in Patent Document 3, a metal-containing azo complex
compound that is a complex between a metal and an azo compound having
as the coupler component a linear β-diketone structure including a
β-ketoester and the like is reported to have absorption in the short
wavelength side in an absorption spectrum. However, the azo compound
having the linear β-diketone structure as the coupler component has
production problems to be improved such as low yield of synthesis,
difficulty in solidification, and low purity of the resulting product, requiring
further studies.

[0008]
Further, the present inventors have reported in Japanese Patent
Application No. 2005-95905 that a metal azo chelate dye composed of a
metal and an azo compound having a diazo component such as isoxazole
having absorption in the short wavelength side and a coupler component
such as pyridone has absorption in the blue light region that corresponds to
350 nm to 530 nm of laser light wavelength. However, further studies have
shown that the foregoing azo compound has a limitation on molecular
designing because the optimum combination of the coupler component and
diazo component is limited, so that further shifting to the shorter
wavelength side is difficult considering the molecular structure thereof. In
addition, it has been also found that the light resistance of the azo
compound containing isoxazole as the diazo component is required to be
improved.
[0009]
The present invention has been made to address the aforementioned
problems that have been highlighted in the course of the development of an
optical recording medium that records and/or reads high density optical
information using a blue laser light of short wavelength.
Namely, it is an object of the present invention to provide an optical
recording medium having a capability of recording and/or reading high
density optical information using a laser light of short wavelength.
Further, it is another object of the present invention to provide an
optical recording material having a capability of recording optical
information using a laser light of short wavelength.
Still further, it is another object of the present invention to provide a
metal complex compound useful as an optical recording material.

Means for solving the problems
[0010]
The present inventors have made intensive studies and found that a
diazo compound having a cyclic p-diketone structure as a coupler
component exhibits a high sensitivity absorption in the short wavelength
side. The present invention has been accomplished based on this finding.
According to the present invention, there is provided an optical
recording medium characterized by comprising a substrate and a recording
layer provided on the substrate directly or on other layers provided on the
substrate, having a capability of recording and/or reading information by
irradiating light thereon wherein the recording layer contains a metal
complex compound composed of an azo compound and a metal ion. The
azo compound has a coupler component with a cyclic p-diketone structure
and a diazo component with a nitrogen-containing heterocyclic aromatic
ring structure. The metal ion is coordinated by the azocompound.
[0011]
The optical recording medium according to the present invention is
not limited as long as the azo compound that composes the metal complex
compound contained in the recording layer has a coupler component with a
cyclic β-diketone structure and a diazo component with a
nitrogen-containing heterocyclic aromatic ring structure, but the coupler
component preferably has a structure of five- to seven-membered ring from
the viewpoint of stability and easiness of the synthesis of the compound.
Particularly preferable is a cyclic p-diketone azo compound represented by
the following general formula (I) or general formula (II). By incorporating
the cyclic p-diketone azo compound into the recording layer, an optical
recording medium having a capability of recording and/or reading high

density optical information using a laser light of short wavelength may be
attained.
[0012]

[0013]
(in the general formula (I) or (II), ring A is a nitrogen-containing
heterocyclic aromatic ring; X, Y, and Z in the general formula (I) and X' and
Y' in the general formula (II) each independently are one kind selected from
an optionally substituted carbon atom, an oxygen atom, a sulfur atom, and
a nitrogen atom and form a five-membered or a six-membered ring together
with a β-diketone structure.)
The coupler component for the cyclic β-diketone azo compound
preferably has a cyclic β-diketone structure having a saturated or
unsaturated five- to seven-membered hydrocarbon ring or a heterocyclic
condensed ring.
[0014]
The diazo component preferably has a nitrogen-containing
heterocyclic aromatic ring structure composed of a five- or six-membered
monocyclic or a dicyclic condensed ring of either or both of a five-membered
ring and a six-membered ring.

Further, the metal ion is preferably an ion of a divalent metal selected
from Groups 7A, 8, 1B, and 2B in the periodic table, particularly preferably
an ion of at least one kind of metal selected from nickel, cobalt, zinc,
copper, and manganese.
[0015]
The optical recording medium according to the present invention has
a recording layer containing the complex composed of the azo compound
having the aforementioned cyclic p-diketone structure and a metal, so that
the optical recording medium is capable of recording information using a
laser light of 350 nm to 530 nm wavelength.
[0016]
Further, according to the present invention, there is provided an
optical recording material that contains a metal-containing cyclic p-diketone
azo compound and, if necessary, the other ingredients. The
metal-containing cyclic p-diketone azo compound is composed of an azo
compound and a metal ion. The azo compound has a coupler component
with a cyclic β-diketone structure and a diazo component with a
nitrogen-containing heterocyclic aromatic ring structure. The metal ion is
coordinated by the azo compound.
Still further, in the metal complex compound composed of an azo
compound having a cyclic β-diketone structure linked to an azo group and a
nitrogen-containing heterocyclic aromatic ring, and a divalent metal ion, the
cyclic β-diketone structure preferably has any structure selected from
Meldrum's acid, tetronic acid, barbituric acid, thiobarbituric acid,
hydroxycoumarin, hydroxycarbostyril, pyrazolidinedione, indandione,
cyclohexanedione, and diketopyrimidine.
Effect of the Invention

[0017]
According to the present invention, an optical recording medium
having a capability of recording and/or reading high density optical
information using a laser light of short wavelength is provided.
Best Mode for Carrying Out the Invention
[0018]
Hereinafter, a best mode for carrying out the present invention
(hereinafter, abbreviated as embodiment) will be explained in detail.
However, the present invention is not limited by the embodiment and may
be performed in various forms within the scope of the present invention.
Further, the accompanying drawings are used to explain the embodiment of
the present invention, but do not show actual sizes.
Further, in the embodiment of the present invention, R1 to R25 defined
in the structural formula described later may optionally have a substituent.
Note that, the "substituent" used in the description of "substituent",
"optionally substituted", and "optionally have a substituent" does not
include a water-soluble group such as a carboxyl group, a sulfonic acid
group and the like.
[0019]
(Azo Compound)
The cyclic β-diketone azo compound (hereinafter, simply mentioned as
"azo compound" in some cases) used in the present embodiment is not
limited as long as the azo compound has a coupler component with a cyclic
β-diketone structure and a diazo component with a nitrogen-containing
heterocyclic aromatic ring structure, but preferably as described above may
have the structure represented by the following general formula (I) or
general formula (II). In the general formula (I) or general formula (II),

generally the nitrogen-containing heterocyclic aromatic ring positioned on
the left side of an azo group (-N=N-) is called the diazo component, and the
cyclic β-diketone structure on the right side is called the coupler
component. The structure represented by the general formula (I) or general
formula (II) may form a keto-enol tautomeric structure. For example, the
structure represented by the general formula (I) may form the following
structure. In the present description, the keto-enol tautomeric structure is
represented by the enol form because a hydrogen atom is eliminated from
the enol form and the resulting -O- form coordinates to the metal ion when
the complex is formed.


(Coupler Component)
Firstly, the coupler component will be explained.
In the coupler component of an azo compound represented by the
general formula (I) or general formula (II), X, X', Y, Y', and Z each
independently represent any one of a carbon atom that optionally has a
substituent except a hydrogen atom, an oxygen atom, a sulfur atom, a
nitrogen atom represented by N-R1, C=O, C=S, and C=NR2, and form a cyclic
P-diketone structure having a five- or six-membered ring structure together
with a 3-diketone structure. R1 represents any one of a hydrogen atom, a
linear or branched alkyl group, a cycloalkyl group, an aralkyl group, an aryl
group, a heterocyclic group, an acyl group represented by -COR3, and an
amino group represented by -NR4R5. R2 represents a hydrogen atom, a
linear or branched alkyl group, or an aryl group. R3 represents a
hydrocarbon group or a heterocyclic group. R4 and R5 each represent a
hydrogen atom, a hydrocarbon atom, or a heterocyclic group. The alkyl
chain moiety thereof or the alkyl chain moiety of the aralkyl group is
optionally substituted by the same substituent as the aforementioned
substituted alkyl chain.
[0023]
A specific example of the cyclic p-diketone structure may be a
structure represented by, for example, cyclohexanedione, Meldrum's acid,
cyclopentadione, pyrazolidinedione, tetronic acid, tetramic acid, barbituric
acid, thiobarbituric acid, indandione, 4-hydroxy-a-pyrone,
4-hydroxy-a-pyridone, 4-hydroxycoumarin, 4-hydroxycarbostyril, or the
like.
[0024]
The combinations or positions of X, X', Y, Y' and Z are not

particularly limited, but when each member is linked together with a single
bond, for example, there may be mentioned the following structures.
[0025]


When X, X', Y, Y', and Z each represent a carbon atom, each
optionally has an alkyl chain as the substituent except a hydrogen atom.
The alkyl chain may be one kind, two of the same kind, or a combination of
different kinds. In addition, X, X', Y, Y', and Z optionally form a spiro ring
at the terminal carbon atoms. Examples of such structures are shown
below, where an alkyl chain is incorporated as a substituent when an
oxygen atom is selected as X and Z and a carbon atom is selected as Y.
[0027]
[Chemical 5]

[0028]
The alkyl chain incorporated as a substituent preferably has from 1
to 16 carbon atoms. When the alkyl chain incorporated as a substituent
is excessively long, the resulting product is likely not to easily solidify and
the gram absorption coefficient that represents absorption per weight is
likely to decrease.
[0029]
Further, when X, X', Y, Y', and Z each are a carbon atom or a
nitrogen atom represented by N-R1, adjacent atoms are optionally linked by
a single bond or a double bond. Such structure having an unsaturated
bonding may include, for example, the following structures.
[0030]
[Chemical 6]


[0031]
Further, when X, X', Y, Y', and Z are each a carbon atom, a nitrogen
atom represented by N-R1, or C=NR2, adjacent atoms are optionally
condensed with each other and form a saturated or unsaturated
hydrocarbon ring or heterocyclic ring. Such a structure may include, for
example, the following structures.
[0032]
[Chemical 7]


[0033]
Among the above condensed structures, there may be mentioned
preferably a saturated or unsaturated five- to seven-membered
hydrocarbon ring or heterocyclic ring, particularly preferably a saturated or
unsaturated six-membered hydrocarbon ring in which every X, X', Y, Y',
and Z adjacent to each other is a carbon at0m.
[0034]
A particularly preferable structure represented by such X, X', Y, Y',
and Z may include the structures shown in the following list:
cyclohexanedione, Meldrum's acid, cyclopentadione, pyrazolidinedione,
tetronic acid, tetramic acid, barbituric acid, thiobarbituric acid,
indandione, 4-hydroxy-a-pyrone, 4-hydroxy-α-pyridone, diketopyrimidine,
4-hydroxycoumarin, and 4-hydroxycarbostyril.
[0035]


[0036]
(Diazo Component)
The diazo component is explained below.
In the general formula (I) or general formula (II), the ring A in the
diazo component represents a nitrogen-containing heterocyclic aromatic
ring formed by including the carbon atom and nitrogen atom bonding to
the ring A. The structure of the nitrogen-containing heterocyclic aromatic

ring may be a monocyclic or a condensed ring as long as the structure has
a nitrogen atom at the position having a coordination capability. The
aromatic ring may include, for example, the following nitrogen-containing
heterocyclic aromatic rings.
[0037]


[0038]
In the nitrogen-containing heterocyclic aromatic ring described
above, D1 to D9 each independently represent any one of a hydrogen atom,
a linear or branched C1-C6 alkyl group, a C3-C9 cycloalkyl group, a
C7-C12 aralkyl group, and an acyl group represented by-COR3.
[0039]
Among the structures described above, in view of the absorption
wavelength or solubility, the structure for the ring A is preferably a
nitrogen-containing heterocyclic aromatic ring composed of a five- or
six-membered monocyclic or a dicyclic condensed ring of either or both of a
five-membered ring and a six-membered ring. Particularly preferably,
there may be mentioned isoxazole, triazole, oxazole, thiadiazole, pyrazole,
pyridine, pyrimidine, imidazole, thiazole, isothiazole, benzothiazole,
benzisoxazole, benzoxazole, and benzimidazole.
[0040]
In the general formula (I) or general formula (II), the ring A may have
any substituent except a hydrogen atom. As an example of the
substituent, there may be mentioned the following groups: for example, an
optionally substituted C1-C18 linear or branched alkyl group such as
methyl, ethyl, propyl, isopropyl, n-butyl, sec-butyl, tert-butyl, n-hepryl and
the like; an optionally substituted C3-C18 cycloalkyl group such as
cyclopropyl, cyclopentyl, cyclohexyl, adamantyl and the like; an optionally
substituted C2-C18 linear or branched alkenyl group such as vinyl,
propenyl, hexenyl and the like; an optionally substituted C3-C18
cycloalkenyl group such as cyclopentenyl, cyclohexenyl and the like; an
optionally substituted saturated or unsaturated heterocyclic group such as
2-thienyl, 2-pyridyl, 4-piperidyl, morpholino and the like; an optionally

substituted C6-C18 aryl group such as phenyl, tolyl, xylyl, mesityl,
naphthyl and the like; an optionally substituted C7-C20 aralkyl group
such as benzyl, phenethyl and the like; an optionally substituted C1-C18
linear or branched alkoxy group such as methoxy, ethoxy, n-propoxy,
isopropoxy, n-butoxy, sec-butoxy, tert-butoxy and the like; an optionally
substituted C3-C18 linear or branched alkenyloxy group such as
propenyloxy, butenyloxy, pentenyloxy and the like; an optionally
substituted C1-C18 linear or branched alkylthio group such as methylthio,
ethylthio, n-propylthio, n-butylthio, sec-butylthio, tert-butylthio and the
like; and others.
[0041]
Further, other specific examples include a halogen atom such as
fluorine, chlorine, bromine and the like; a nitro group; a cyano group; a
mercapto group; a hydroxyl group; a formyl group; an acyl group
represented by -COR3; an amino group represented by -NR4R5; an
acylamino group represented by -NHCOR6; a carbamate group represented
by -NHCOOR7; a carboxylate group represented by -COOR8; an acyloxy
group represented by -OCOR9; a carbamoyl group represented by
-CONR10R11; a sulfonyl group represented by -SO2R12; a sulfinyl group
represented by -SOR13; a sulfamoyl group represented by -SO2NR14R15; a
sulfonate group represented by -SO3R16; and a sulfone-amide group
represented by -NHSO2R17. The bonding position of the foregoing
substituents is not particularly limited, and the number of the
substituents may be zero to two or more. The plural substituents may be
the same or different.
[0042]
In the foregoing substituents, R3, R6, R7, R8, R9, R12, R13, R16, and R17

each represent a hydrocarbon group or a heterocyclic group. R4, R5, R10,
R11, R14, and R15 each represent any one of a hydrogen atom, a
hydrocarbon group, and a heterocyclic group. The substituents are
optionally substituted if necessary.
[0043]
The hydrocarbon group represented by R3 to R17 includes, for
example, a C1-C18 linear or branched alkyl group such as methyl, ethyl,
propyl, isopropyl, n-butyl, sec-butyl, tert-butyl, n-heptyl and the like; a
C3-C18 cycloalkyl group such as cyclopropyl, cyclopentyl, cyclohexyl,
adamantyl and the like; a C2-C18 linear or branched alkenyl group such
as vinyl, propenyl, hexenyl and the like; a C3-C18 cycloalkenyl group such
as cyclopentenyl, cyclohexenyl and the like; a C7-C20 aralkyl group such
as benzyl, phenethyl and the like; and a C6-C18 aryl group such as
phenyl, tolyl, xylyl, mesityl and the like. The alkyl chain and aryl group
moieties are further optionally substituted by a substituent that may be
incorporated in the alkyl chain moiety of R2 to R5 described later.
[0044]
Further, the heterocyclic group represented by R3 to R17 may include
a saturated heterocyclic ring such as 4-piperydyl, morpholino,
2-morpholinyl, piperazyl and the like; and a heterocyclic aromatic ring
such as 2-furyl, 2-pyridyl, 2-thiazolyl, 2-quinolyl and the like. These
heterocyclic groups optionally have plural heteroatoms and further a
substituent. In addition, the heterocyclic group may be bonded at any
position. A preferable structure of the heterocyclic group may be a
saturated five- or six-membered heterocyclic ring or a heterocyclic aromatic
ring including a five- or six-membered monocyclic or a dicyclic condensed
ring of either or both of a five-membered ring and a six-membered ring.

[0045]
Hereinafter, a specific chemical structure is exemplified for the
aforementioned acyl group, amino group, acylamino group, carbamate
group, carboxylate group, acyloxy group, carbamoyl group, sulfonyl group,
sulfinyl group, sulfamoyl group, sulfonate group, and sulfone-amide group.
As the acyl group (-COR11), there may be mentioned the functional
groups having the following structures, and the like.
[0046]

[0047]
As the amino group (-NR12R13), there may be mentioned the
functional groups having the following structures, and the like.
[0048]
[Chemical 11]


[0049]
As the acylamino group (-NHCOR14), there may be mentioned the
functional groups having the following structures, and the like.
[0050]

[0051]
As the carbamate group (-NHCOOR15), there may be mentioned the
functional groups having the following structures, and the like.
[0052]
[Chemical 13]


[0053]
As the carboxylate group (-COOR16), there may be mentioned the
functional groups with the following structures, and the like.
[0054]

[0055]
As the acyloxy group (-OCOR17), there may be mentioned the
functional groups with the following structures, and the like.
[0056]
[Chemical 15]


[0057]
As the carbamoyl group (-CONR18R19), there may be mentioned the
functional groups with the following structures, and the like.
[0058]

[0059]
As the sulfonyl group (-SO2R20), there may be mentioned the
functional groups with the following structures, and the like.
[0060]

[Chemical 17]

[0061]
As the sulfinyl group (-SOR21), there may be mentioned the
functional groups with the following structures, and the like.
[0062]
[Chemical 18]

[0063]
As the sulfamoyl group (-SO2NR22R23), there may be mentioned the
functional groups with the following structures, and the like.
[0064]
[Chemical 19]


[0065]
As the sulfonate group (-SO3R24), there may be mentioned the
functional groups with the following structures, and the like.
[0066]
[Chemical 20]

[0067]
As the sulfone-amide group (-NHSO2R25), there may be mentioned the
functional groups with the following structures, and the like.
[0068]
[Chemical 21]


[0069]
In the aforementioned general formula (1) or general formula (II), the
substituent including the linear or branched alkyl group, the cycloalkyl
group, the linear or branched alkenyl group, the cycloalkenyl group, linear
or branched alkoxy group, and linear or branched alkylthio group, and the
alkyl chain moiety of an alkyl group represented by R3 to R17 may further
have a substituent. As the substituent, there may be mentioned, for
example, a C1-C10 alkoxy group such as methoxy, ethoxy, n-propoxy,
isopropoxy, n-butoxy, sec-butoxy, tert-butoxy and the like; a C2-C12
alkoxyalkoxy group such as methoxymethoxy, ethoxymethoxy,
propoxymethoxy, ethoxyethoxy, propoxyethoxy, methoxybutoxy and the like;
a C3-C15 alkoxyalkoxyalkoxy group such as methoxymethoxymethoxy,
methoxymethoxyethoxy, methoxyethoxymethoxy, ethoxyethoxymethoxy and
the like; a C6-C12 aryloxy group such as phenoxy, tolyloxy, xylyloxy,
naphthyloxy and the like; a C2-C12 alkenyloxy group such as allyloxy,
vinyloxy and the like; and others.
[0070]
Further, as the substituent, there may be mentioned besides those
mentioned above, a heterocyclic group such as 2-thienyl, 2-pyridyl,

4-piperidyl, morpholino and the like; a cyano group; a nitro group; a
hydroxyl group; a mercapto group; an alkylthio group such as
methylmercapto, ethylmercapto and the like; a C1~C10 alkylamino group
such as amino, N,N-dimethylamino, N,N-diethylamino and the like; a C1~C6
alkylsulfonylamino group such as methylsulfonylamino, ethylsulfonylamino,
n-propylsulfonylamino and the like; a halogen atom such as fluorine,
chlorine, bromine and the like; an alkylcarbonyl group such as
methylcarbonyl, ethylcarbonyl, isopropylcarbonyl and the like; a C2-C7
alkoxycarbonyl group such as methoxycarbonyl, ethoxycarbonyl,
n-propoxycarbonyl, isopropoxycarbonyl, n-butoxycarbonyl and the like; a
C2~C7 alkylcarbonyloxy group such as methylcarbonyloxy,
ethylcarbonyloxy, n-propylcarbonyloxy, isopropylcarbonyloxy,
n-butylcarbonyloxy and the like; a C2~C7 alkoxycarbonyloxy group such as
methoxycarbonyloxy, ethoxycarbonyloxy, n-propoxycarbonyloxy,
isopropoxycarbonyloxy, n-butoxycarbonyloxy and the like; and others.
[0071]
As the substituent of the ring A in the diazo component, there is no
particular limitation, but from the viewpoint of easiness of synthesis,
solubility in a coating solvent, and others, there may be mentioned
preferably a hydrogen atom, a C1~C12 linear or branched alkyl group, a
C3~C10 cycloalkyl group, a C2~C12 linear or branched alkenyl group, a
C7~C18 aralkyl group, a C1~C12 linear or branched alkoxy group, a
C1-C12 linear or branched alkylthio group, a C6~C18 aryl group, a
saturated or unsaturated heterocyclic group, a halogen atom, a nitro group,
a cyano group, a mercapto group, a hydroxyl group, a formyl group, an acyl
group represented by -COR11, an amino group represented by -NR4R5, an
acylamino group represented by -NHCOR6, a carbamate group represented

by -NHCOOR7, a carboxylate group represented by -COOR8, an acyloxy
group represented by -OCOR9, a carbamoyl group represented by
-CONR10R11, a sulfonyl group represented by -SO2R12, a sulfinyl group
represented by -SOR13, a sulfamoyl group represented by -SO2NR14R15, a
sulfonate group represented by -SO3R16, and a sulfone-amide group
represented by -NHSO2R17.
[0072]
The molecular weight of the azo compound represented by the general
formula (I) or general formula (II) is preferably 1,000 or less and particularly
preferably 700 or less. Too large molecular weight is rather undesirable
because the gram absorption coefficient is lowered and the absorption
becomes low with respect to the amount of the dye.
As a preferable example of the azo compound represented by the
general formula (I) or general formula (II), there may be mentioned the
following compounds of (1) to (189).
[0073]
[Chemical 22]


[0074]
[Chemical 23]


[0075]
[Chemical 24]































[0090]
(Metal)
Hereinafter, there will be explained the metal that forms, by
coordinating with the azo compound represented by the general formula (I)
or general formula (II), the metal-containing cyclic β-diketone azo compound

that is a metal complex compound.
As the metal that forms, by coordinating with the azo compound
represented by the general formula (I) or general formula (II), the
metal-containing cyclic β-diketone azo compound, any kind of metal may be
selected without limitation as long as the metal has a capability of
coordination with the azo compound. There may be selected a transition
element or a representative element, that may have any oxidation number.
The ratio between the metal and the azo compound is not particularly
limited in the metal-containing cyclic β-diketone azo compound. The
complex may contain a charged counter ion besides the azo compound and
the metal. The metal may include, for example, a metal selected from
Group 7A, 8, 1B, and 2B in the periodic table. Among these metals, nickel,
cobalt, copper, iron, zinc, manganese, platinum, palladium, and the like are
preferably selected.
[0091]
(Metal Complex Compound)
As mentioned above, the azo compound represented by the general
formula (I) or general formula (II) forms a metal complex compound by
coordinating with the metal that has a capability of being coordinated with
the azo compound. In terms of the easiness of forming the complex, the
complex structure formed from the azo compound and the metal is
preferably the structure (hexa-coordinated structure) formed by
coordination of two azo compounds to one divalent transition metal because
the azo compound easily transforms into a tridentate ligand having minus
one charge. In particular, a coordinated structure with a divalent
transition metal such as nickel, cobalt, copper, iron, zinc, and manganese is
preferable. Further, plural kinds of the azo compounds may coordinate to

the metal as a ligand to form the metal-containing cyclic p-diketone azo
compound. Still further, plural kinds of the metal-containing cyclic
β-diketone azo compounds may be contained in the recording layer.
[0092]
As the metal complex compound, there may be mentioned, for
example, the following compounds: a metal complex compound having as a
ligand an azo compound composed of a coupler component based on
Meldrum's acid and a diazo component selected from isoxazole,
benzisoxazole, pyrazole, triazole, imidazole, benzimidazole, thiazole,
benzothiazolethiadiazole, and pyridine; a metal complex compound having
as a ligand an azo compound composed of a coupler component based on
tetronic acid and a diazo component selected from isoxazole, benzisoxazole,
pyrazole, triazole, imidazole, benzimidazole, thiazole, benzothiazole,
thiadiazole, and pyridine; a metal complex compound having as a ligand an
azo compound composed of a coupler component based on
hydroxycoumarin and a diazo component selected from isoxazole,
benzisoxazole, pyrazole, triazole, imidazole, benzimidazole, thiazole,
benzothiazole, thiadiazole, and pyridine; a metal complex compound having
as a ligand an azo compound composed of a coupler component based on
hydroxycarbostyril and a diazo component selected from isoxazole,
benzisoxazole, pyrazole, triazole, imidazole, benzimidazole, thiazole,
benzothiazole, thiadiazole, and pyridine; a metal complex compound having
as a ligand an azo compound composed of a coupler component based on
indandione and a diazo component selected from isoxazole, benzisoxazole,
pyrazole, triazole, and benzimidazole; a metal complex compound having as
a ligand an azo compound composed of a coupler component based on
barbituric acid and a diazo component selected from isoxazole,

benzisoxazole, pyrazole, triazole, and benzimidazole; and a metal complex
compound having as a ligand an azo compound composed of a coupler
component based on thiobarbituric acid and a diazo component selected
from isoxazole, benzisoxazole, pyrazole, triazole, and benzimidazole. By
selecting appropriately the combination of the diazo component and the
coupler component, the wavelength of the absorption band, absorbance,
and solubility of the metal complex compound may be conditioned at
desired values.
[0093]
(Optical Recording Medium)
Hereinafter, the optical recording medium to which the present
embodiment is applied is explained. The optical recording medium in
accordance with the present embodiment has at least a substrate and a
recording layer that contains a metal-containing cyclic β-diketone azo
compound given by coordinating a metal to an azo compound represented
by the general formula (I) or general formula (II) (hereinafter, in some cases
simply described as "metal-containing cyclic β-diketone azo compound").
If necessary, an underlying layer, a reflection layer, a protection layer, and
others may be further provided.
[0094]
FIGURE 1 shows a first embodiment of an optical recording medium
100 to which the present embodiment (CD-R is shown in the embodiment)
is applied. The optical recording medium 100 shown in FIG. 1 has a
substrate 10 made of a transparent material and has a guide groove 11
and an information recording layer 20 disposed on the substrate 10. The
information recording layer 20 is composed of a recording layer 21 having a
reflection layer 22 and a protection layer 23 that are laminated in this

order on the recording layer 21. The optical recording medium 100 has a
capability of recording and/or reading information by laser light irradiated
from the side of the substrate 10. For the convenience of explanation, in
the optical recoding medium 100, the side where the protection layer 23 is
disposed is called as upper, and the side where the substrate 10 is
disposed is called as lower. Each face of each layer corresponding to the
foregoing upper and lower directions is called as the upper or lower face of
each layer.
[0095]
(Substrate 10)
For the substrate 10, various kinds of materials can be used as long
as the material is basically transparent at the wavelengths of recording
light and reading light. Specifically, there may be mentioned resins such
as acrylic, methacrylic, polycarbonate, polyolefin (especially, amorphous
polyolefin), polyester, polystyrene, epoxy and the like; and glass. In
addition, there may be mentioned a structure having a resin layer of a
radiation curable resin such as a photo-curable resin on a glass substrate.
Among the materials, considering high productivity, cost, moisture
resistance and the like, polycarbonate resin used by injection molding is
preferable. Considering chemical and moisture resistances, amorphous
polyolefin is preferable. Further, considering fast response performance
and the like, glass is preferable. In the case where the substrate 10 made
of a resin is used or where the substrate 10 having a resin layer on the side
(upper side) contacting the recording layer 21 is used, guide grooves or pits
for recording and reading light may be formed on the upper face. As the
shape of the guide groove, there may be mentioned a concentric ring form
and a spiral form having the same center with the optical recording

medium 100. In the case of the guide groove having a spiral form, the
groove pitch is preferably around 0.2 µm to 1.2 µm.
[0096]
(Recording Layer 21)
The recording layer 21 is formed directly on the upper side of the
substrate 10, or if necessary, on the upper side of an underlying layer and
the like disposed on the substrate 10, and contains the metal-containing
cyclic β-diketone azo compound given by coordinating metal to an azo
compound represented by the general formula (I) or general formula (II).
As the method of forming the recording layer 21, there may be mentioned
various conventional thin film forming processes including vacuum
deposition method, sputtering method, doctor-blade method, casting
method, spin-coating method, dipping method, and the like. The
spin-coating method is preferred in terms of mass productivity and cost,
while the vacuum deposition method or the like is more preferred than
coating method in terms of obtaining the recording layer 21 with a uniform
thickness. In the case of film forming process using spin-coating, the
number of revolutions is preferably 500 rpm to 15,000 rpm. Further, if
necessary, after spin-coating, additional treatments such as heating and
exposure to solvent vapor may be performed.
[0097]
In the case of forming the recording layer 21 using the coating
process such as doctor-blade coating, casting, spin-coating, and dipping,
any coating solvent used to dissolve and coat the metal-containing cyclic
β-diketone azo compound on the substrate 10 may be used without any
particular limitations as long as the coating solvent does not erode the
substrate 10. Specifically, there may be mentioned, for example, ketone

alcohols such as diacetone alcohol, 3-hydroxy-3-methyl-2-butanone and
the like; cellosolves such as methylcellosolve, ethylcellosolve and the like;
linear hydrocarbons such as n-hexane, n-octane and the like; cyclic
hydrocarbons such as cyclohexane, methyl cyclohexane, ethyl cyclohexane,
dimethyl cyclohexane, n-butyl cyclohexane, tert-butyl cyclohexane,
cyclooctane and the like; perfluoroalkylalcohols such as
tetrafluoropropanol, octafluoropentanol, hexafluorobutanol and the like;
hydroxycarboxylates such as methyl lactate, ethyl lactate, methyl
2-hydroxyisolactate and the like; and others.
[0098]
In the case of using the vacuum deposition process, for example,
recording layer components including the metal-containing cyclic
β-diketone azo compound and if necessary other dyes or various kinds of
additives are put in a crucible placed in a vacuum chamber; the inside of
the vacuum chamber is evacuated to a pressure of 10-2 Pa to 10-5 Pa with
an appropriate vacuum pump; the crucible is heated to evaporate and
deposit the recording layer components on a substrate placed to face the
crucible. In this way, the recording layer 21 is formed.
[0099]
Further, in the recording layer 21, in addition to the
metal-containing cyclic β-diketone azo compound, for the purpose of
improving stability and light resistance, there may be contained various
additives including, for example, a singlet-oxygen quencher such as a
transition metal chelate compound (for example, acetylacetonate chelate,
bisphenyldithiol, salicylaldehyde-oxime, bisdithio-a-diketone and the like),
still further, for the purpose of improving recording sensitivity, there may
be contained a recording sensitivity improver such as a metal compound.

The metal compound refers to a compound that contains a metal such as a
transition metal in the form of atoms, ions, or clusters, including, for
example, an organometallic compound such as an ethylenediamine
complex, an azomethine complex, a phenylhydroxyamine complex, a
phenanthroline complex, a dihydroxyazobenzene complex, a dioxime
complex, a nitrosoaminophenol complex, a pyridyltriazine complex, an
acetylacetonate complex, a metallocene complex, and a porphyrin complex.
The metal atom is not particularly limited, but preferably a transition
metal.
[0100]
In addition, in the recording layer 21, if necessary, plural kinds of
the metal-containing cyclic β-diketone azo compounds may be used in
combination. Further, besides the metal-containing cyclic p-diketone azo
compound, if necessary, the other kinds of dyes may be used in
combination. The other kinds of dyes are not particularly limited as long
as the dyes have an adequate absorption in the oscillation wavelength
range of a laser light used for recording. Further, there may be
incorporated in the recording layer 21 together with the metal-containing
cyclic β-diketone azo compound, a dye used for CD-R and the like and has
an adequate performance for recording and reading using a nearinfrared
laser light having an oscillation wavelength in the range of 770 nm to 830
nm, or a dye used for DVD-R and the like and has an adequate
performance for recording and reading using a red laser light having an
oscillation wavelength in the range of 620 nm to 690 nm. In this way, the
optical recording medium 100 that meets the recording and reading using
plural kinds of laser lights belonging to different wavelength ranges may be
produced.

[0101]
The other kinds of dyes besides the metal-containing cyclic
β-diketone azo compound may include a metal-containing azo dye, a
benzophenone dye, a phthalocyanine dye, a naphthalocyanine dye, a
cyanine dye, an azo dye, a squarylium dye, a metal-containing indoaniline
dye, a triarylmethane dye, a merocyanine dye, an azulenium dye, a
naphthoquinone dye, an anthraquinone dye, an indophenol dye, a
xanthene dye, an oxazine dye, a pyrilium dye, and the like.
[0102]
Still further, if necessary, a binder, a leveling agent, a defoaming
agent, and the like may be used in combination. A preferable binder may
include polyvinylalcohol, polyvinylpyrrolidone, nitrocellulose, cellulose
acetate, a ketone resin, an acrylic resin, a polystyrene resin, a urethane
resin, polyvinylburyral, polycarbonate, polyolefin, and the like.
[0103]
The thickness of the recording layer 21 is not particularly limited
because a suitable thickness differs depending on recording methods and
others, but is generally at least 1 nm or more and preferably 5 nm or more
because a certain thickness is required for recording. However, adequate
recording may not be attained when the thickness is too large, so that the
thickness is generally 300 nm or less, preferably 200 nm or less, and more
preferably 100 nm or less.
[0104]
The reflection layer 22 is formed on the recording layer 21. The
thickness of the reflection layer 22 is preferably 50 nm to 300 nm. As the
material for the reflection layer 22, a material having a sufficiently high
reflectance at the wavelength of light used for reading may be used. For

example, there may be used a metal such as Au, Al, Ag, Cu, Ti, Cr, Ni, Pt,
Ta, Pd, and others, solely or as an alloy. Among the metals, Au, Al, and
Ag have a high reflectance and are suitable for the reflection layer 22.
Further, other materials may be incorporated in the above metals that are
used as a main component. Here, the main component is defined as the
one that has a content of 50% or more.
[0105]
The other materials besides the main component may include, for
example, a metal or a semimetal such as Mg, Se, Hf, V, Nb, Ru, W, Mn, Re,
Fe, Co, Rh, Ir, Cu, Zn, Cd, Ga, In, Si, Ge, Te, Pb, Po, Sn, Bi, Ta, Ti, Pt, Pd,
Nd and the like. Among the above other materials, a material containing
Ag as a main component is particularly preferable from the viewpoint of
low cost, easily providing high reflectance, attaining a clean white ground
color when a printing receiving layer mentioned later is disposed, and
others.
[0106]
For example, an alloy containing Ag and 0.1 atom% to 5 atom% of at
least one kind of metal selected from Au, Pd, Pt, Cu, and Nd is desirable
because the alloy provides high reflectance, high durability, and high
sensitivity with low cost. Specifically, for example, there may be
mentioned an Ag-Pd-Cu alloy, an Ag-Cu-Au alloy, an Ag-Cu-Au-Nd alloy,
an Ag-Cu-Nd alloy, and the like. As a material other than a metal, a
multi-layered film given by stacking alternatively a low refraction thin film
and a high refraction thin film may be used as the reflection layer 22.
[0107]
As the method of forming the reflection layer 22, there may be
mentioned a process such as sputtering, ion-plating, chemical vapor

deposition, vacuum deposition and the like. Further, on the substrate 10
or under the reflection layer 22, for the purpose of increasing reflectance,
improving recording performance, and improving adhesion, a known
inorganic or organic intermediate or adhesive layer may be disposed.
[0108]
The protection layer 23 is formed on the reflection layer 22. The
material for the protection layer 23 is not particularly limited as long as the
material has a capability of protecting the reflection layer 22 against
external forces. As an organic material, there may be mentioned a
thermoplastic resin, a thermosetting resin, an electron beam curable resin,
a UV light curable resin, and the like.
[0109]
As an inorganic material, there may be mentioned silicon oxide,
silicon nitride, MgF2, SnCO2, and the like. In the case of using the
thermoplastic resin or thermosetting resin, a coating solution prepared by
dissolving the resin in an appropriate solvent is coated on the reflection
layer 22 and dried to form the protection layer 23. In the case of using the
UV light curable resin, the resin is coated as it is on the reflection layer 22,
or a coating solution prepared by dissolving the resin in an appropriate
solvent is coated on the reflection layer 22, and then the coating is cured
by irradiating UV light thereon, so that the protection layer 23 may be
formed.
[0110]
As the UV light curable resin, for example, there may be used an
acrylate resin such as urethane aerylate, epoxy aerylate, polyester acrylate
and the like. The foregoing materials may be used alone or in a
combination of two or more kinds. Further, the protection layer may be a

single layer or a multiple layer.
[0111]
As the method of forming the protection layer 23, similarly to the
recording layer 21, a coating process such as spin-coating and casting,
sputtering, chemical vapor deposition or the like may be used, and
spin-coating is preferable in particular. The thickness of the protection
layer 23 is generally 0.1 µm or more and preferably 3 µm or more because
a certain thickness is required to provide an adequate protection effect.
However, the thickness is generally 100 µm or less and preferably 30 µm
or less because, when the protection layer 23 becomes too thick, not only
would no change in the protection effect be expected but also
disadvantages of high cost or long production time would be possibly
brought about.
[0112]
As a layered structure of the optical recording medium 100, a
structure formed by stacking the substrate 10, the recording layer 21, the
reflection layer 22, and the protection layer 23 in this order is exemplified
as above, but the other layered structures may be employed. For example,
on the upper face of the protection layer 23 in the above exemplified
structure, or on the upper face of the reflection layer 22 in the case where
the protection layer 23 is removed from the above exemplified structure, an
additional substrate may be bonded together. The additional substrate
may be a bare substrate having no layers thereon or a substrate having an
arbitrary layer such as a reflection layer on the bonding face or the
opposite face thereof. Furthermore, an optical recording medium having
the layered structure exemplified above and an optical recording medium
given by removing the protection layer from the layered structure

exemplified above may be bonded together in a manner that each upper
face of the protection layer and/or reflection layer faces each other.
[0113]
Hereinafter, a second embodiment of the optical recording medium
will be described.
FIGURE 2 shows a second embodiment of an optical recording
medium 200 to which the present embodiment (an air incident type media
is exemplified here) is applied. The portions similar to the optical recording
medium 100 according to the first embodiment are represented by the
same reference numbers, and the explanations thereof are omitted.
[0114]
The optical recording medium 200 shown in FIG. 2 has a substrate
30 having a predetermined guide groove 31, and an information recording
layer 40 disposed on the substrate 30. In the information recording layer
40, a recording layer 41 and a protection film 43 are laminated in this
order on a reflection layer 42. The optical recording medium 200 performs
recording and reading of information with a laser light irradiated from the
side of the protection film 43.
[0115]
The protection film 43 may be a film or sheet bonded with an
adhesive, or may be formed by coating and curing or drying a film-forming
coating solution prepared from the same material as the aforementioned
protection layer 23 (FIG. 1). The thickness of the protection film 43 is
generally 0.1 µm or more and preferably 3 µm or more because a certain
thickness is required to provide an adequate protection effect. However,
the thickness is generally 300 µm or less and preferably 200 µm or less
because, when the protection film 43 becomes too thick, not only would no

change in the protection effect be expected but also disadvantages of high
cost or long production time would be possibly brought about. Similar
layers used in the aforementioned optical recording medium 100 (FIG. 1)
may be used for the each layer such as the recording layer 41 and the
reflection layer 42. Note that, in the present layered structure, the
substrate 30 is not required to be transparent. Therefore, besides the
aforementioned materials, there may be used opaque resins, ceramics,
metals (including alloys) and the like. In such layered structure, an
arbitrary layer may be interposed between the aforementioned layers as
long as the properties in accordance with the present invention are not
impaired.
[0116]
As one of the methods for increasing the recording density of the
optical recording media 100 and 200, there may be mentioned a method of
increasing the numerical aperture (NA) of an objective lens. The size of a
light spot focused on the information recording face may be micronized
using this method. However, the increase in the numerical aperture (NA)
of the objective lens possibly brings about the increase in the aberration of
the light spot caused by the warp and the like of the optical recording
media 100 and 200 when laser light is irradiated for recording and reading.
Under such conditions, an adequate, stable recording and reading of
signals is not attained in some cases. Such aberration tends to become
larger as the thickness of the transparent substrate or protection film
through which laser light passes becomes larger, so that it is desirable that
the substrate or protection film be designed as thin as possible. However,
generally, since the substrates 10 and 30 are required to have a certain
thickness to assure the mechanical strength of the optical recording media

100 and 200, it is preferable to employ the structure of the optical
recording medium 200 (that is, the optical recording medium 200 having a
basic layered structure composed of the substrate 30, reflection layer 42,
recording layer 41, and protection film 43) in this case. The optical
recording medium 200 is preferably used because the thickness of the
protection film 43 of the optical recording medium 200 may be reduced
more easily as compared with the substrate 10 of the optical recording
medium 100.
[0117]
Note that, even in the structure of the optical recording medium 100
(that is, the optical recording medium 100 having a basic layered structure
composed of the substrate 10, recording layer 21, reflection layer 22, and
protection layer 23), by reducing to around 50 µm to 300 µm the thickness
of the transparent substrate 10, through which a recording and reading
laser light passes, the aberration may be reduced to such an extent that
the optical recording medium becomes usable. Further, after the other
layers are formed, a UV light curable resin layer or an inorganic thin film
may be formed on the incident face of a recording and reading laser light
(generally, the lower face of the substrate 10) to protect the face or to
prevent dust deposition. On a face other than the laser light incident face
(generally, the upper face of the reflection layer 22 or protection layer 23),
there may be formed a print receiving layer capable of being drawn or
printed with various printers such as an ink-jet and a thermal head, or
various pens and pencils.
[0118]
In the optical recording media 100 and 200 in accordance with the
present embodiments, the laser light used for recording and reading of

information has preferably a wavelength as short as possible to attain high
density recording. In particular, a laser light having a wavelength of 350
nm to 530 nm is preferable. As a typical laser light having such
wavelength, there may be mentioned laser lights having s center
wavelengths of 405 nm, 410 nm, and 515 nm.
[0119]
The laser light having a wavelength of 350 nm to 530 nm may be
obtained by using a high power semiconductor laser light having
wavelengths of 405 nm and 410 nm of blue color and a wavelength of 515
nm of blue-green color. Besides the above, the laser light may be also
obtained, for example, by converting the wavelength of either of the
following oscillating laser light using a second harmonic generator (SHG):
(a) a semiconductor laser light having a fundamental oscillation wavelength
of 740 nm to 960 nm and a capability of continuous wave oscillation; and
(b) a solid-state laser light excited by a semiconductor laser light and has a
fundamental oscillation wavelength of 740 nm to 960 nm and a capability
of continuous wave oscillation.
[0120]
Here, as the SHG, any piezo element free from reversal symmetry
may be usable, but KDP, ADP, BNN, KN, LBO, compound semiconductors,
and the like are preferable. As the specific example of the second
harmonic, in the case of a semiconductor laser light having a fundamental
wavelength of 860 nm, there may be mentioned 430 nm that is a
double-frequency wave, and in the case of the solid-state laser light excited
by a semiconductor laser, there may be mentioned 430 nm that is a
double-frequency wave generated from a Cr-doped LiSrAlF6 crystal (having
a fundamental oscillation wavelength of 860 nm).

[0121]
When information is recorded in the optical recording media 100 and
200 according to the present embodiments, a laser light focused in around
0.4 µm to 0.6 µm is irradiated, on the recording layer 21 through the
substrate 10 from the side of the substrate 10, in the case of the optical
recording medium 100, and on the recording layer 41 through the
protection film 43 from the side of the protection film 43 in the case of the
optical recording medium 200. The portions of the recording layers 21
and 41 that are irradiated by the laser light absorb the energy of the laser
light and cause thermal deformation such as decomposition, heat
generation, and fusion, resulting in changes in the optical properties.
When the information recorded in the recording layers 21 and 41 is read, a
laser light having a lower energy is irradiated on the recording layers 21
and 41 (generally, from the same side as in recording). In the recording
layers 21 and 41, the difference in reflectance between a portion subjected
to a change in optical properties (that is, an information recorded portion)
and another portion subjected to no change is read out to read the
information.
Example
[0122]
The present embodiments are explained in more detail by the
following Examples, but the present embodiments are not limited by the
Examples as long as the embodiments are within the scope thereof.
[0123]
(Synthesis Method)
The method of synthesizing the metal-containing cyclic p-diketone azo
compound is not particularly limited, but generally there may be mentioned

the following synthesis method. Firstly, a heterocyclic aromatic amine is
diazotized in an acidic solution by adding sodium nitrite or nitrosylsulfuric
acid, so that a diazo component is synthesized. Secondly, the resulting
diazo component is added dropwise at around 0°C to a solution that
dissolves a coupler component to synthesize an azo compound.
Subsequently, to a solution dissolving the resulting azo compound in an
appropriate solvent, a solution of a metal salt is added dropwise to
synthesize a metal complex compound. The following example shows a
structure of a metal complex compound having a 2:1 composition of a diazo
compound and a divalent metal ion.
[0124]
[Chemical 39]

[0125]
(Example 1)
(a) Synthesis example
In a solution containing 25 ml of acetic acid, 8.5 ml of propionic acid,
and 1 ml of cone, sulfuric acid, 2.45 g of 3-amino-5-methylisoxazole (0.025
mol, manufactured by Tokyo Chemical Industry Co., Ltd.) represented by
the following structural formula (1) were dissolved with stirring and the
resulting solution was cooled at 0°C to 5°C. To this solution, 8.85 g of 43%

nitrosyl sulfuric acid was added dropwise, while the temperature of the
solution was kept at 10°C or lower, to prepare a diazo solution. On the
other hand, in another vessel, 5 g of 1,3-diethyl-2-thiobarbituric acid (0.025
mol, manufactured by Aldrich Corp.) represented by the following structural
formula (2), 7.5 g of sodium acetate, and 1 g of urea were dissolved in 100
ml of methanol and 20 ml of water with stirring. After the pH of the
resulting solution was adjusted at 5 with hydrochloric acid, the solution
was cooled to 0°C to 5°C.
[0126]
[Chemical 40]

[0127]
To this solution, the aforementioned diazo solution was added
dropwise at a temperature of 5°C or lower while the pH was kept at 4 to 5
with a 14% aqueous ammonia. After the addition, the resulting reaction
solution was stirred for 30 minutes, and then filtered. The filtered product
was suspended in 500 ml of water to remove inorganic salt. After
30-minute stirring, the suspension was filtered. Further, the filtered
product was suspended in 200 ml of methanol, and the resulting
suspension was stirred and filtered. The filtered product was dried by
heating under vacuum to obtain 6.847 g of an azo compound (yield: 88.5%).
MS measurement (EI) of the azo compound was done, and the azo
compound was confirmed to have m/z = 309 that coincided with those of
the target compound (example compound (115)).
[0128]

1H-NMR (CDCl3 (δ = ppm) MHz) of the example compound (115) was
measured. The results were: 1.31 (6H, t, 1, 3N-CH2CH3), 2.46 (3H, s,
5'-CH3), 4.55 (4H, m, 1, 3N-CH2CH3), and 6.51 (1H, s, 4'-H). The peaks of
the results coincided with those of the objective compound. The example
compound (115) exhibited Amax = 383.5 nm and a molar absorption
coefficient of 3.9×104 in chloroform. FIGURE 3 shows the spectrum of the
example compound (115) in solution.
[0129]
[Chemical 41]

[0130]
Next, 1.86 g (0.006 mol) of the example compound (115) was dissolved
in 46 ml of tetrahydrofuran with stirring. The resulting solution was
filtered to remove insolubles. To the filtrate, a solution dissolving 0.896 g
(0.0036 mol) of nickel acetate in 15 ml of methanol was added dropwise.
The resulting reaction solution was stirred for 1 hour and
vacuum-evaporated with an evaporator, to distill out the solvent and to
deposit a solid. To the solid, 50 ml of water was added. The resulting
mixture was stirred and filtered. The filtered product was washed with
isopropyl ether, and then dried by heating under vacuum to obtain 1.66 g
(yield: 81.7%) of a compound represented by the following structural
formula (3) (the product obtained was called metal complex compound (1)).
The metal complex compound (1) exhibited Amax = 428 nm and a
molar absorption coefficient of 5.4×104 in chloroform. FIGURE 4 shows the

spectrum of the metal complex compound (1) in solution.
[0131]
[Chemical 42]

[0132]
(b) Evaluation of optical recording medium
The aforementioned metal complex compound (1) was dissolved in
octafluoropentanol to obtain a 1 wt% solution. After filtration, the solution
was added dropwise on an injection-molded polycarbonate resin substrate
disk 0.6 mm thick, 120 mm in diameter to be spin-coated (at 500 rpm).
After the coating, the resulting coating was dried at 100°C for 30 min. The
resulting coating film had a maximum absorption wavelength (Amax) at
427.5 nm. The spectrum of the coating film obtained by coating the metal
complex compound (1) is shown in FIGURE. 5.
[0133]
A chip of the substrate disk coated with the metal complex compound
(1) was irradiated with a Xe lamp of 550 mW at 63°C for 40 hours, using a
light resistance tester (SUNTEST XLS+, manufactured by Toyo Seiki
Seisaku-Sho, Ltd.). After that, the absorbance at Amax before the Xe lamp
irradiation and the absorbance at Amax after the Xe lamp irradiation were
measured using a UV measuring instrument. The ratio (%) of the
absorbance after the Xe lamp irradiation with respect to the absorbance
before the Xe lamp irradiation was 55.1%. Note that, the larger the value of
the absorbance is, the better the light resistance is.

[0134]
In addition, on the coating film thus prepared, if necessary, a
reflection layer of Ag or the like is formed by sputtering, further a UV light
curable resin is coated by spin-coating or the like and cured by UV light
irradiation to form a protection layer, so that an optical recording medium
may be obtained. The optical recording medium has a recording and
reading capability, depending on the λmax value of the coating film, for
example, with a semiconductor laser light having a center wavelength of 405
nm. Namely, it is found that the metal-containing cyclic 0-diketone azo
compound has a molecular structure workable for blue laser recording.
[0135]
(Method of preparing optical recording media and example of recording)
The aforementioned metal complex compound (1) was dissolved in
tetrafluoropropanol to obtain a 0.9 wt% solution. After filtration, the
resulting solution was added dropwise and spin-coated on an injection
molded polycarbonate resin substrate disk 0.6 mm thick, 120 mm in
diameter having a track pitch of 400 nm, a groove width of 220 nm, and a
groove depth of 60 nm. The spin-coating revolution was increased from
800 rpm to 7,000 rpm in 13 seconds and kept at 7,000 rpm for 2 seconds.
Then, the resulting coating was dried at 75°C for 18 minutes to form a
recording layer. After that, a silver alloy was sputtered on the recording
layer to form a 120 nm thick reflection layer. Then, a protection coating
agent of a UV light curable resin was spin-coated on the disk, and the disk
was irradiated with a UV light to form a 5 µm thick protection layer. Still
further, using a delayed curing adhesive, another 0.6 mm thick
polycarbonate substrate disk was bonded to the face on the protection layer
side to prepare an optical recording medium for evaluation.

[0136]
(c) Example of recording
While the foregoing optical recording medium for evaluation was
rotated at a linear velocity of 6.61 m/sec, a single frequency signal of 8T
mark and 8T space was recorded on the groove with a laser light of 405 nm
wavelength (the numerical aperture of an objective lens, NA = 0.65). Here,
T is a fundamental clock frequency corresponding to a frequency of 65 MHz.
The recording pulse strategy was as follows: the number of the divided
pulses was (n-1) when the mark length was nT; the forefront recording pulse
width was 2T; the following recording pulse width was 0.5T; the bias power
was 3.0 mW; the reading power was 0.4 mW; and the recording power was
variable. As a result, a signal with a modulation degree of 51% was
recorded at 7.5 mW. The modulation degree is considered to become larger
by optimizing the recording conditions such as the pulse strategy.
[0137]
(Example 2)
(a) Synthesis example
In a solution containing 50 ml of acetic acid, 35 g of phosphoric acid,
and 5 g of conc, sulfuric acid, 3.5 g of 2-aminothiazole (0.035 mol,
manufactured by Tokyo Chemical Industry Co., Ltd.) represented by the
following structural formula (4) was dissolved and the resulting solution was
cooled at 0°C to 5°C. To this solution, 12.39 g of 43% nitrosyl sulfuric acid
was added drop wise while the temperature of the solution was kept at 10°C
or lower to prepare a diazo solution. On the other hand, in another vessel,
5.3 g of a compound (1.05 equivalent amount, manufactured by Tokyo
Chemical Industry Co., Ltd.) represented by the following structural formula
(5), 10.5 g of sodium acetate, and 1.4 g of urea were dissolved in a solution

of 140 ml of methanol and 35 ml of water. After the pH of the resulting
solution was adjusted at 5 with hydrochloric acid, the solution was cooled
to 0°C to 5°C.
[0138]
[Chemical 43]

[0139]
To this solution, the aforementioned diazo solution was added
dropwise at a temperature of 5°C or lower while the pH was kept at 4 to 5
with a 14% aqueous ammonia. After the addition, the resulting reaction
solution was stirred for 30 minutes, and then filtered. The filtered product
was suspended in 500 ml of water to remove inorganic salt. After
30-minute stirring, the suspension was filtered. Further, the filtered
product was suspended in 150 ml of methanol, and the resulting
suspension was stirred and filtered. The filtered product was dried by
heating under vacuum to obtain 6.458 g of an azo compound (yield: 72.3%).
The azo compound exhibited λmax = 384.5 nm and a molar absorption
coefficient of 1.7×104 in chloroform.
[0140]
The azo compound was subjected to the MS measurement (EI), and
was confirmed to have m/z = 255 that coincided with an objective
compound. The azo compound was subjected to the 1H-NMR
measurement (CDCl3 (δ = ppm) MHz). The results were as follows: 1.83
(6H, s, 2, 2-CH3), 7.12 (1H, d, 5'-H), 7.55 (1H, d, 4'-H), and 13.76 (1H, s,

6-OH). The peaks of the results coincided with those of the objective
compound (example compound (116)).
[0141]
[Chemical 44]

[0142]
In 28 ml of tetrahydrofuran, 1.53 g (0.006 mol) of the example
compound (116) was dissolved while stirring. The resulting solution was
filtered to remove insolubles. To the filtrate, a solution containing 0.9 g
(0.0036 mol) of nickel acetate tetrahydrate in 16 ml of methanol was added
dropwise. The resulting reaction solution was stirred for 1 hour, and then
filtered to separate a product. The resulting solid product was washed with
water, and then dried by heating under vacuum to obtain 1.552 g (yield:
91.2%) of a compound represented by the following structural formula (6)
(the product obtained was called metal complex compound (2).) The
example metal complex compound (141) exhibited λmax = 420.5 nm and a
molar absorption coefficient of 3.9×104 in chloroform.
[0143]
[Chemical 45]

[0144]

(b) Evaluation of optical recording medium
The aforementioned metal complex compound (2) was dissolved in
octafluoropentanol to obtain a 1 wt% solution. After filtration, the solution
was added dropwise on an injection-molded polycarbonate resin substrate
disk 0.6 mm thick, 120 mm in diameter to be spin-coated. After the
coating, the resulting coating was dried at 100°C for 30 min. The resulting
coating film had a maximum absorption wavelength (λmax) at 423.5 nm.
The spectrum of the coating film obtained by coating the metal complex
compound (2) is shown in FIGURE. 6.
[0145]
An optical recording medium was prepared as follows. A chip of the
substrate disk coated with the metal complex compound (2) was irradiated
with a Xe lamp of 550 mW at 63°C for 40 hours, using a light resistance
tester (SUNTEST XLS+, manufactured by Toyo Seiki Seisaku-Sho, Ltd.) to
evaluate light resistance in the same manner as in Example 1. The light
resistance was 97.2%.
[0146]
The aforementioned metal complex compound (2) was dissolved in
tetrafluoropropanol to obtain a 0.9 wt% solution. After filtration, the
resulting solution was added dropwise and spin-coated on an injection
molded polycarbonate resin substrate disk 0.6 mm thick, 120 mm in
diameter having a track pitch of 400 nm, a groove width of 220 nm, and a
groove depth of 60 nm. The spin-coating revolution was increased from
800 rpm to 7,000 rpm in 13 seconds and kept at 7,000 rpm for 2 seconds.
Then, the resulting coating was dried at 75°C for 18 minutes to form a
recording layer. After that, a silver alloy was sputtered on the recording
layer to form a 120 nm thick reflection layer. Then, a protection coating

agent of a UV light curable resin was spin-coated, irradiated with a UV light
to form a 5 µm thick protection layer. Still further, using a delayed curing
adhesive, another 0.6 mm thick polycarbonate substrate disk was bonded to
the face on the protection layer side to prepare an optical recording medium
for evaluation.
[0147]
(c) Example of recording
While the foregoing optical recording medium for evaluation was
rotated at a linear velocity of 6.61 m/sec, a single frequency signal of 8T
mark and 8T space was recorded on the groove with a laser light of 405 nm
wavelength (the numerical aperture of an objective lens, NA = 0.65). Here,
T is a fundamental clock frequency corresponding to a frequency of 65 MHz.
The recording pulse strategy was as follows: the number of the divided
pulses was (n-1) when the mark length was nT; the forefront recording pulse
width was 2T; the following recording pulse width was 0.5T; the bias power
was 3.0 mW; the reading power was 0.4 mW; and the recording power was
variable. As a result, a signal with a modulation degree of 51% was
recorded at 6.5 mW. The modulation degree is considered to become larger
by optimizing the recording conditions such as the pulse strategy.
[0148]
(Example 3)
(a) Synthesis example
In 28 ml of tetrahydrofuran, 1.53 g (0.006 mol) of the example
compound (116) synthesized in Example 2 was dissolved while stirring.
The resulting solution was filtered to remove insolubles. To the filtrate, a
solution containing 0.9 g (0.0036 mol) of cobalt acetate in 16 ml of methanol
was added dropwise. The resulting reaction solution was stirred for 1

hour; and then filtered to separate a product. The resulting solid product
was washed with water, and then dried by heating under vacuum to obtain
1.22 g (yield: 71.6%) of a compound represented by the following structural
formula (7). The compound exhibited Amax = 417.5 nm and a molar
absorption coefficient of 3.3×104 in chloroform (the product obtained was
called metal complex compound (3).)
[0149]
[Chemical 46]

[0150]
(b) Evaluation of optical recording medium
The metal complex compound (3) was dissolved in octafluoropentanol
to obtain a 1 wt% solution. After filtration, the resulting solution was
added dropwise on an injection-molded polycarbonate resin substrate disk
0.6 mm thick, 120 mm in diameter to be spin-coated. After that, the
resulting coating was dried at 100°C for 30 min. The resulting coating film
had a maximum absorption wavelength (Amax) at 420.5 nm. The spectrum
of the coating film obtained by coating the metal complex compound (3) is
shown in FIGURE. 7.
[0151]
A chip of the substrate disk coated with the metal complex compound
(3) was irradiated with a Xe lamp of 550 mW at 63°C for 40 hours, using a
light resistance tester (SUNTEST XLS+, manufactured by Toyo Seiki
Seisaku-Sho, Ltd.) to evaluate light resistance in the same manner as in

Example 1. The light resistance was 94.1%.
[0152]
Method of preparing optical recording media and example of recording
The aforementioned metal complex compound (3) was dissolved in
tetrafluoropropanol to obtain a 0.9 wt% solution. After filtration, the
resulting solution was added dropwise and spin-coated on an injection
molded polycarbonate resin substrate disk 0.6 mm thick, 120 mm in
diameter having a track pitch of 400 nm, a groove width of 220 nm, and a
groove depth of 60 nm. The spin-coating revolution was increased from
800 rpm to 7,000 rpm in 13 seconds and kept at 7,000 rpm for 2 seconds.
Then, the resulting coating was dried at 75°C for 18 minutes to form a
recording layer. After that, a silver alloy was sputtered on the recording
layer to form a 120 nm thick reflection layer. Then, a protection coating
agent of a UV light curable resin was spin-coated, irradiated with a UV light
to form a 5 µm thick protection layer. Still further, using a delayed curing
adhesive, another 0.6 mm thick polycarbonate substrate disk was bonded to
the face on the protection layer side to prepare an optical recording medium
for evaluation.
[0153]
(c) Example of recording
While the foregoing optical recording medium for evaluation was
rotated at a linear velocity of 6.61 m/sec, a single frequency signal of 8T
mark and 8T space was recorded on the groove with a laser light of 405 nm
wavelength (the numerical aperture of an objective lens, NA = 0.65). Here,
T is a fundamental clock frequency corresponding to a frequency of 65 MHz.
The recording pulse strategy was as follows: the number of the divided
pulses was (n-1) when the mark length was nT; the forefront recording pulse

width was 2T; the following recording pulse width was 0.5T; the bias power
was 3.0 mW; the reading power was 0.4 mW; and the recording power was
variable. As a result, a signal with a modulation degree of 48.4% was
recorded at 6.4 mW. The modulation degree is considered to become larger
by optimizing the recording conditions such as the pulse strategy.
[0154]
(Examples 4 to 151)
By using the synthesis method similarly to the method mentioned
above, an example azo compound (115) to an example azo compound (189)
were synthesized, and further converted to metal complex compounds.
Absorption spectra of coating films prepared similarly to Example 1 were
measured. The maximum absorption wavelength and molar absorption
coefficient in a solution (chloroform) of the metal complex compounds, and
the maximum absorption wavelength of the coating films
(octafluoropentanol or tetrafluoropropanol was selected as a coating solvent
as appropriate) were measured. Further, the coating films were subjected
to the light resistance test. The results are shown in Tables 1 to 7 together
with the results of Examples 1 to 3.
[0155]



[0156]



[0157]



[0158]



[0159]



[0160]



[0161]


[0162]
The wavelength of the metal-containing cyclic β-diketone azo

compound is determined by the combination of the diazo component, the
coupler component, and the metal ion. In the case of selecting the same
coupler component and the metal, a compound having a long wavelength
may be obtained by using a diazo component having a longer wavelength.
Similarly, in the case of selecting the same diazo component and the metal,
a metal-containing cyclic β-diketone azo compound having a longer
wavelength may be obtained by using a coupler component having a longer
wavelength. The wavelength may become longer or shorter depending on
the substituents and the like, but generally the following tendency may be
drawn within the range of the present Examples.
[0163]
[Chemical 47]
[0164]
The tendency may vary depending on the combination with the
coupler component or the kinds of metals, but the light resistance roughly
depends on the diazo component in many respects. The diazo component
such as isoxazole and triazole that has a shorter wavelength is likely to
provide a rather lower light resistance, while the diazo component such as
thiazole and benzothiazole that has a longer wavelength provides a good
light resistance. Therefore, a compound having a large light resistance may

be synthesized from a coupler component having a shorter wavelength and
a diazo component having a longer wavelength. Besides the
aforementioned combinations of the diazo component and coupler
component, a compound that meets an objective wavelength may be
synthesized by selecting the substituent of the diazo component or selecting
the kind of the metals. In this way, for example, the metal-containing
cyclic β-diketone azo compounds shown in Table 1 may be used over a wide
wavelength range of from 368.5 nm to 482 nm.
[0165]
In addition, on the coating film thus prepared, if necessary, Ag and
the like may be sputtered to form a reflection layer, further a UV light
curable resin may be spin-coated and cured by UV light irradiation to form
a protection layer. In this way, an optical recording medium may be
obtained. The optical recording medium has a recording and reading
capability, for example, depending on the Amax value of the coating film,
with a semiconductor laser light having a center wavelength of 405 nm.
Namely, it is found that the metal-containing cyclic 3-diketone azo
compound composed of an azo compound represented by the general
formula (I) or general formula (II) and metal has a molecular structure
workable for blue laser recording.
[0166]
The results shown in Tables 1 to 7 indicate that the light resistance of
the metal complex compound is likely to be affected by the diazo
component, the coupler component, or the kind of metal ion. For example,
when isoxazole is selected as the diazo component (Examples 1, 5, 8, 23 to
27, 38, and 41), the maximum value of the light resistance is only as large
as 65.2%. In the case of Examples 2 and 3 where metal complexes

compound having the same coupler component are used, the light
resistance exceeds 90%. As opposed to Examples 2 and 3, in the case of
Example 8 in which a metal complex compound having a coupler
component different from the coupler component used in Examples 2 and 3,
the light resistance is only 42.9%. Still further, in the case of Example 25
in which a metal complex compound composed of an azo compound and Co
ion is used, the light resistance is 65.2%. As opposed to Example 25, in
the case of Example 27 in which a metal complex compound composed of
the same azo compound as above and Zn ion is used, the light resistance
decreases to 1.7%.
[0167]
A metal complex compound having a small light resistance may be
admixed with another metal complex compound having an adequate light
resistance or an organic dye compound and the like used for conventional
CD-Rs and others, for example, so that the light resistance may be improved
to a practical level required for optical recording media.
[0168]
Further, the metal complex compound having a small light resistance
may be effectively admixed with a compound having a singlet oxygen
quenching effect (for example, acetylacetonate chelate, bisphenyldithiol,
salicylaldehyde-oxime, bisdithio-a-diketone, and the like).
[0169]
(Comparative Example 1)
For comparison, the following compound (8) was synthesized and
evaluated in terms of an optical recording medium,
(a) Preparation example
From 2-amino-6-methylbenzothiazole (manufactured by Tokyo

Chemical Industry Co., Ltd.) represented by the following structural formula
(8) and l-n-butyl-3-cyano-4-methyl-6-hydroxy-2-pyridone, the following
compound (9) was synthesized. The compound (9) exhibited a Amax of
453.5 nm and a molar absorption coefficient of 3.2×104 in chloroform.

The compound (9) was subjected to chelation using nickel acetate to
obtain the following compound (10). The compound (10) exhibited a Amax
at 524 nm and a molar absorption coefficient of 7.4×104 in chloroform.
[0173]

(b) Example of Optical recording medium
The compound (10) was added to octafluoropentanol to prepare a 1

wt% solution, but the compound (10) had a poor solubility and about half of
the compound (10) added remained undissolved. After filtration, the
resulting solution was added dropwise on an injection molded polycarbonate
resin substrate disk 0.6 mm thick, 120 mm in diameter to be spin-coated
(500 rpm). The resulting coating was dried at 100°C for 30 minutes. The
resulting coating film had a maximum absorption wavelength (λmax) at
542.5 nm. However, the absorption at a wavelength of 405 nm was quite
small. Recording using a laser light having a center wavelength of 405 nm
is found not to be expected.
[0175]
FIGURE 8 shows the absorption spectrum of the compound (10). The
absorption spectrum is shown together with the spectrum of a nickel
compound (Example 15) that used Meldrum's acid as a coupler component.
FIGURE 8 shows that the compound (10) is not an adequate dye
compound for use in recording with a blue laser light, because the
compound (10) has a different coupler component even though the
compound (10) is a metal-containing azo compound using as the diazo
component the same benzothiazole as the complex compound of Example
15 that exhibited a large absorption at 405 nm.
[0176]
(Comparative Example 2)
For comparison, the following compound (11) was synthesized and
evaluated in terms of an optical recording medium,
(a) Preparation example
In a similar method, 2-amino-5-methyl-l,3,4-thiadiazole
(manufactured by Tokyo Chemical Industry Co., Ltd.) was diazotized, and
subjected to coupling reaction under the same conditions as in Example 1

to synthesize the following compound (11). The compound (11) exhibited a
Amax at 409.5 nm and a molar absorption coefficient of 3.0×104 in
chloroform.
[0177]
[Chemical 51]

[0178]
The compound (11) was subjected to the chelation using nickel
acetate in a manner similar to Comparative Example 1 to obtain the
following compound (12). The compound (12) exhibited a Amax at 494 nm
and a molar absorption coefficient of 7.1x104 in chloroform. FIGURE 9
shows the absorption spectrum of the compound (12). The absorption
spectrum is shown together with the spectrum of a nickel complex (Example
32) that used barbituric acid as a coupler component. FIGURE 9 shows
that the compound (12) is not an adequate dye compound for use in
recording with a blue laser light as opposed to the metal complex compound
of Example 32 that exhibited a large absorption at 405 nm.
[0179]
[Chemical 52]

[0180]

(b) Example of Optical recording medium
The compound (12) was added to octafluoropentanol to prepare a 1
wt% solution, but the compound (12) had a poor solubility and almost all of
the compound (12) added remained undissolved. After filtration, the
resulting solution was added dropwise on an injection molded polycarbonate
resin substrate disk 0.6 mm thick, 120 mm in diameter to be spin-coated
(500 rpm). The resulting coating was dried at 100°C for 30 minutes.
Because of the poor solubility, the resulting coating film provided no
absorption spectrum.
The above result shows that when the pyridone structure is used as
the coupler component, the wavelength becomes long enough even though
1,3,4-thiadiazole is used as the diazo component, so that benzothiazole or
thiazole mentioned in the previous section is obviously useless.
[0181]
(Comparative Example 3)
For comparison, an azo compound was synthesized using a linear
β-diketone as the coupler component,
(a) Preparation example
In a solution containing 6 ml of acetic acid, 2 ml of propionic acid,
and 1.3 ml of conc, sulfuric acid, 1.4 g of 2-amino-4-methylthiazole (0.013
mol, manufactured by Tokyo Chemical Industry Co., Ltd.) represented by
the following structural formula (13) was dissolved while stirring, and the
resulting solution was cooled at 0°C to 5°C. To this solution, 4.6 g of 43%
nitrosyl sulfuric acid was added dropwise while the temperature of the
solution was kept at 10°C or lower to prepare a diazo solution.
[0182]
On the other hand, in another vessel, 2.8 g of thenoyltrifluoroacetone

(1 equivalent amount, manufactured by Tokyo Chemical Industry Co., Ltd.),
4.3 g of sodium acetate, and 0.43 g of urea were dissolved in a solution of
50 ml of methanol and 5 ml of water. After the pH of the resulting solution
was adjusted at 11 with a 20% aqueous NaOH solution, the solution was
cooled at 0°C to 5°C. To the solution, the foregoing diazo solution was
added dropwise at a temperature of 5°C or lower while the pH was kept at
10 with an aqueous ammonia. After the addition was over, the resulting
solution was stirred for 30 minutes, and then filtered. The resulting filtrate
was poured into water and the resulting solution was acidified by adding
conc, hydrochloric acid dropwise to deposit a reaction product. The
reaction product was filtered, washed with water, and dried by heating
under vacuum to obtain 0.96 g of a compound represented by the following
chemical formula (15) with a yield of 21%.
[0183]
FIGURE 10 shows the absorption spectrum of the compound
represented by the chemical formula (15). The compound represented by
the chemical formula (15) has a λmax at 399.5 nm and a molar absorption
coefficient of 1.0x104 in chloroform. As is shown, the yield of the
compound represented by the chemical formula (15) is low and the molar
absorption coefficient is also low.


[Chemical 54]

[0186]
(Comparative Example 4)
For comparison, the following compound (16) that has a comparable
absorption at λmax was evaluated in terms of an optical recording medium.
The cyanine dye (trade name: NK-1204, manufactured by Nippon
Kanko Shikiso Kenkyusho Co., Ltd.) represented by the following structural
formula (16) exhibited a Amax at 407.5 nm and a molar absorption
coefficient of 8.2×104 in chloroform. FIGURE 11 shows the spectrum of the
compound in solution.
[0187]
[Chemical 55]

[0188]
The compound (16) was dissolved in octafluoropentanol to prepare a 1
wt% solution, which was then filtered. The resulting solution was added
dropwise and spin-coated (500 rpm) on an injection-molded polycarbonate
resin substrate disk 0.6 mm thick, 120 mm in diameter. The coating was
dried at 100°C for 30 minutes. The resulting coating film had a maximum

absorption wavelength (λmax) at 371.5 nm. FIGURE 12 shows the spectrum
of the coating film.
As is clear when the spectrum is compared with the spectrum in
solution shown in FIG. 11, the spectrum of the coating film is extremely
deformed. This deformation is possibly caused by partial crystallization of
the coating on the surface of the substrate disk, although the crystallization
was not observed by visual inspection.
A chip of the substrate disk coated with the cyanine dye was
subjected to the evaluation of absorption ratio at Amax (light resistance)
similarly to Example 1. The light resistance was 18%.
[0189]
(Comparative Example 5)
For similar comparison, the following compound (17) was evaluated in
terms of an optical recording medium.
The compound 2-[2-furan-2-yl]
vinyl]-4,6-bis(trichloromethyl)-l,3,5-triazine (manufactured by Tokyo
Chemical Industry Co., Ltd.) represented by the following formula (17)
exhibited a λmax at 375 nm in chloroform and the molar absorption
coefficient of 3.5×104.
[0190]
[Chemical 56]

[0191]

The compound (17) was dissolved in methyl lactate to prepare a 1 wt%
solution, which was then filtered. The resulting solution was added
dropwise and spin-coated (500 rpm) on an injection-molded polycarbonate
resin substrate disk 0.6 mm thick, 120 mm in diameter. The coating was
dried at 100°C for 30 minutes. The surface of the substrate disk became
clouded by crystallization. A spectrum adequate for evaluation was not
obtained.
[0192]
As is clear from the results of comparative Examples 4 and 5, even
though dyes exhibit absorption in a similar range of wavelength, the film
forming capability or light resistance thereof required for an optical
recording medium is greatly different. Generally, crystallization in the
course of forming the coating film is likely to develop remarkably as the
molecule becomes smaller or the molecule has a higher planarity in the
molecular structure. The metal-containing azo complex compound used in
Examples of the present invention is composed of two molecules of an azo
dye and one metal ion, having a sterically-bulky molecular structure,
thereby seems to have characteristics less liable to crystallize on the surface
of the substrate. In addition, a higher light resistance may be provided by
forming the complex than by using the azo dye alone. As mentioned above,
it is quite obvious that the present invention provides an extremely useful
dye for an optical recording medium.
[0193]
As mentioned above, it is shown that, as the coupler component, a
cyclic β-diketone structure has a higher yield and provides a compound
having a larger molar absorption coefficient than a linear β-diketone
structure. This may be attributed to the following reasons: when the

coupler component has a ring structure, the active methylene group that
serves as a reactive site is fixed and provides a higher reactivity; the
reaction product has a tendency of getting a more planar structure and
allows the conjugated system to extend more easily; and others.
[0194]
(Example 152)
The optical recording medium obtained in Example 1 was subjected to
PRSNR (Partial Response SNR) evaluation in accordance with the HD DVD-R
standard Ver 1.0 defined by DVD Forum for evaluating the recording and
reading performance of optical recording media.
The optical recording medium obtained was recorded at a linear
velocity of 6.61 m/s and a shortest mark length of 204 nm using a tester
(ODU-1000, manufactured by Pulsetech Corp.) having a laser wavelength of
405 nm and a NA (numerical aperture) of 0.65. The recording power was
optimized to obtain a maximum value of PRSNR.
The results were as follows: the recording mechanism was of the
Low-To-High type; and the optimized recording power was 7.8 mW. The
PRSNR value of the optical recording medium was 32.8, which exceeded
substantially the standard PRSNR value of 15.
[0195]
(Examples 153 to 198)
Optical recording media were prepared under the same conditions as
in Example 152 except that the compounds shown in Tables 8 to 10 were
used as dyes, and were evaluated in the same method as in Example 152.
Here, recording sensitivity or recording characteristics depend on the
thickness of a thin layer of the dye or the recording method, so that the
concentration of the coating solution (0.9 wt% to 1.2 wt%), the spin-coating

program, the groove shape of the substrate disk, the recording pulse width,
and others were optimized to obtain an adequate recording performance.
[0196]
The optimized recording power and the value of PRSNR of Examples
153 to 198 are shown in Tables 8 to 10 together with the results of Example
152. As is clear from the results shown in Tables 8 to 10, many Examples
clear the HD and DVD-R standard of the recording sensitivity of 10 mW or
lower and PRSNR =15. In addition, the recording mechanism was of the
Low-To-High type.






[0200]
The values of the recording sensitivity and recording characteristics
may vary with the structure of dyes, the spectral form, the onset
temperature of thermal decomposition of dyes, the kind of metal forming
the complex, and others. For example, when Example 153 is compared
with Example 157 that used the same' coupler component but has
absorption shifted to a longer wavelength, Example 157 yielded a lower
PRSNR value. Considering the above results, the recording performance is
likely to be lowered when the λmax of the coating film of dyes departs
substantially from 405 nm. This is because the recording principle is
based on the Low-To-High type, and a certain degree of absorption is
required at the recording wavelength. Therefore, it is obvious that a
coupler component providing absorption at shorter wavelength is required
to enhance the recording performance.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

[0201]
FIGURE 1 is a view for explaining a first embodiment of an optical
recording medium (CD-R) to which the present embodiment is
applied.
FIGURE 2 is a view for explaining a second embodiment of an
optical recording medium (an air incident type media) to which
the present embodiment is applied.
FIGURE 3 shows the spectrum of the example compound (115) in
solution.
FIGURE 4 shows the spectrum of the metal complex compound (1)
in solution.
FIGURE 5 shows the spectrum of the coating film obtained by
coating the metal complex compound (1).
FIGURE 6 shows the spectrum of the coating film obtained by
coating the metal complex compound (2).
FIGURE 7 shows the spectrum of the coating film obtained by
coating the metal complex compound (3).
FIGURE 8 shows the absorption spectrum of the compound (10)(full
line) and complex compound (dash line) of Example 15.
FIGURE 9 shows the absorption spectrum of the compound (12)(full
line) and complex compound (dash line) of Example 32.
FIGURE 10 shows the absorption spectrum of the compound
represented by the chemical formula (15).
FIGURE 11 shows the absorption spectrum of the compound
represented by the chemical formula (16).
FIGURE 12 shows the absorption spectrum of the coating film of
the compound represented by the chemical formula (16).

Description of Reference Numerals and Signs
[0202]
10,30 ••• substrate
11,31... guide groove
20.40...information recording layer
21.41...recording layer
22.42...reflection layer
23...protection layer
43 • • • protection film
100,200...optical recording medium

WE CLAIM :
1. An optical recording medium comprising:
a substrate; and
a recording layer which is provided on the substrate directly or on
other layers provided on the substrate, having a capability of recording
and/or reading information by irradiating a laser light thereon, the laser
light having a wavelength of from 350 nm to 530 nm,
wherein the recording layer contains a metal complex compound
comprising an azo compound having a coupler component with a cyclic
β-diketone structure and a diazo component with a nitrogen-containing
hererocyclic aromatic ring structure, and a divalent metal ion
coordinated by the azocompound, and
wherein the coupler component has any one of the structures
selected from Meldrum's acid, tetronic acid, barbituric acid,
thiobarbituric acid, hydroxycoumarin, hydroxycarbostyril,
pyrazolidinedione, indandione, cyclohexanedione, and diketopyrimidine.
2. The optical recording medium as claimed in claim 1, wherein
the diazo component has a nitrogen-containing heterocyclic
aromatic ring structure composed of a five- or six-membered monocyclic
or a dicyclic condensed ring of either or both of a five-membered ring and
a six-membered ring.

3. The optical recording medium as claimed in claim 1, wherein
the metal ion is an ion of a metal selected from Groups 7A, 8, 1B,
and 2B in the periodic table.
4. The optical recording medium as claimed in claim 1, wherein
the metal ion is an ion of at least one kind of metal selected from
nickel, cobalt, zinc, copper, and manganese.
5. A metal complex compound comprising:
an azo compound having a cyclic β-diketone structure bonded to
an azo group and a nitrogen-containing heterocyclic aromatic ring; and
a divalent metal ion,
wherein the cyclic β-diketone structure has any one of the
structures selected from Meldrum's acid, tetronic acid, barbituric acid,
thiobarbituric acid, hydroxycoumarin, hydroxycarbostyril,
pyrazolidinedione, indandione, cyclohexanedione, and diketopyrimidine.


ABSTRACT

OPTICAL RECORDING MEDIUM, OPTICAL RECORDING
MATERIAL AND METAL COMPLEX COMPOUND
An optical recording medium is disclosed. The medium comprises: a substrate; and a
recording layer which is provided on the substrate directly or on other layers provided on the
substrate, having a capability of recording and/or reading information by irradiating a laser
light thereon, the laser light having a wavelength of from 350 nm to 530 nm, wherein the
recording layer contains a metal complex compound comprising an azo compound having a
coupler component with a cyclic β-diketone structure and a diazo component with a
nitrogen-containing hererocyclic aromatic ring structure, and a divalent metal ion
coordinated by the azocompound, and wherein the coupler component has any one of the
structures selected from Meldrum's acid, tetronic acid, barbituric acid, thiobarbituric acid,
hydroxycoumarin, hydroxycarbostyril, pyrazolidinedione, indandione, cyclohexanedione,
and diketopyrimidine.

Documents:

00056-kolnp-2008-abstract.pdf

00056-kolnp-2008-claims.pdf

00056-kolnp-2008-correspondence others.pdf

00056-kolnp-2008-description complete.pdf

00056-kolnp-2008-drawings.pdf

00056-kolnp-2008-form 1.pdf

00056-kolnp-2008-form 3.pdf

00056-kolnp-2008-form 5.pdf

00056-kolnp-2008-gpa.pdf

00056-kolnp-2008-international publication.pdf

00056-kolnp-2008-pct priority document notification.pdf

00056-kolnp-2008-pct request form.pdf

56-KOLNP-2008-(06-07-2012)-CORRESPONDENCE.pdf

56-KOLNP-2008-(06-07-2012)-FORM-3.pdf

56-KOLNP-2008-(06-07-2012)-OTHERS.pdf

56-KOLNP-2008-(25-07-2012)-ABSTRACT.pdf

56-KOLNP-2008-(25-07-2012)-AMANDED CLAIMS.pdf

56-KOLNP-2008-(25-07-2012)-AMANDED PAGES OF SPECIFICATION.pdf

56-KOLNP-2008-(25-07-2012)-DESCRIPTION (COMPLETE).pdf

56-KOLNP-2008-(25-07-2012)-DRAWINGS.pdf

56-KOLNP-2008-(25-07-2012)-EXAMINATION REPORT REPLY RECEIVED.pdf

56-KOLNP-2008-(25-07-2012)-FORM-2.pdf

56-KOLNP-2008-(25-07-2012)-OTHERS.pdf

56-KOLNP-2008-(25-07-2012)-PETITION UNDER RULE 137.pdf

56-KOLNP-2008-ASSIGNMENT.pdf

56-KOLNP-2008-CORRESPONDENCE OTHERS 1.1.pdf

56-KOLNP-2008-CORRESPONDENCE.pdf

56-KOLNP-2008-EXAMINATION REPORT.pdf

56-KOLNP-2008-FORM 18 1.1.pdf

56-kolnp-2008-form 18.pdf

56-KOLNP-2008-FORM 3 1.1.pdf

56-KOLNP-2008-FORM 3-1.1.pdf

56-KOLNP-2008-FORM 5.pdf

56-KOLNP-2008-GPA.pdf

56-KOLNP-2008-GRANTED-ABSTRACT.pdf

56-KOLNP-2008-GRANTED-CLAIMS.pdf

56-KOLNP-2008-GRANTED-DESCRIPTION (COMPLETE).pdf

56-KOLNP-2008-GRANTED-DRAWINGS.pdf

56-KOLNP-2008-GRANTED-FORM 1.pdf

56-KOLNP-2008-GRANTED-FORM 2.pdf

56-KOLNP-2008-GRANTED-SPECIFICATION.pdf

56-KOLNP-2008-INTERNATIONAL PUBLICATION.pdf

56-KOLNP-2008-OTHERS.pdf

56-KOLNP-2008-PCT REQUEST FORM.pdf

56-KOLNP-2008-REPLY TO EXAMINATION REPORT.pdf

abstract-00056-kolnp-2008.jpg


Patent Number 254297
Indian Patent Application Number 56/KOLNP/2008
PG Journal Number 42/2012
Publication Date 19-Oct-2012
Grant Date 17-Oct-2012
Date of Filing 03-Jan-2008
Name of Patentee MITSUBISHI KAGAKU MEDIA CO., LTD
Applicant Address 31-19 SHIBA 5-CHOME, MINATO-KU TOKYO
Inventors:
# Inventor's Name Inventor's Address
1 KIMURA MAYUMI C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
2 MIYAZAWA TAKASHI C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
3 SHODA HISASHI C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
4 SATAKE KENICHI C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
5 TAKAHASHI YUKIKO C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
6 UCHIDA NAOYUKI C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
7 TAMAGAWA HIDEKI C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
8 KUROSE YUTAKA C/O MITSUBISHI KAGAKU MEDIA CO., LTD, 31-19 SHIBA 5-CHOME, MINATO-KU, TOKYO 108-0014
PCT International Classification Number C09B 45/18,B41M 5/26
PCT International Application Number PCT/JP2006/313761
PCT International Filing date 2006-07-11
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2005-205830 2005-07-14 Japan