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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an information recording medium and a
recording method using the same.
2. Description of the Related Art
A conventional recordable/erasable information recording medium includes a
substrate, a first protective layer, a recording layer, a second
protective layer, and a reflecting layer.
When a recording/erasing operation is to be performed using such an
information recording medium, a light beam is radiated on the entire
surface of the information recording medium to heat the information
recording medium at a temperature lower than the melting point of the
material of the recording layer, thereby setting the material of a
recording layer in a high crystallinity (a state in which atoms are
relatively regularly arranged; to be referred to as a crystalline state
hereinafter). Strong pulse light having a short wavelength is radiated on
the information recording medium to heat and melt the recording layer, and
the recording layer is rapidly cooled. In this manner, part on which the
pulse light is radiated has a low crystallinity (a state in which an
atomic arrangement is disturbed; to be referred to as an amorphous state
hereinafter).
As described above, since the crystalline and amorphous states have
different atomic arrangement structures, these states have different
optical characteristics such as transmittances or reflectances.
Information can be recorded by using the difference between the optical
characteristics. Information recorded as described above can be erased as
follows. That is, weak pulse light having a long wavelength is radiated on
the recorded portion to heat the recorded portion to a temperature which
is equal to or lower than the melting point of the material constituting
the recording layer, and the recorded portion is gradually cooled. This is
because the state of the material of the recorded portion is returned to
the original state, i.e., the crystalline state.
In an actual information recording medium, a change in reflectance between
the crystalline state and the amorphous state is used as a signal as
described above. For this reason, the thickness of each layer is designed
in consideration of the optical interference effects of the interface
between the protective layer and the recording layer and the interface
between the protective layer and the reflecting layer. Therefore,
according to the optical constants of the materials used in the
information recording medium, there are optimal thicknesses capable of
obtaining a large change in reflectance.
The following fact is known. That is, when the thickness of the protective
layer increases, heat flowing from the recording layer to the reflecting
layer is interfered, and rapid cooling cannot be satisfactorily controlled
by modulation of a laser power, thereby degrading recording
characteristics. Therefore, in a conventional technique, when GeSbTe or
the like is used as the material of the recording layer, the thickness of
the protective layer is set to fall within a range of 100 to 200A, thereby
performing recording such that the reflectance decreases (T. Ohta et al.
JJAP. Vol. 128 (1989) SUPPLEMENT 28-3, pp. 123-128).
As a recording method using such an information recording medium described
above, mark position recording and mark length recording are known. That
is, recording marks having the same shape are formed, and information is
obtained by intervals between the centers of the recording marks. In the
mark length recording, recording marks having lengths corresponding to
information are formed, and information is obtained by the lengths of the
recording marks.
In a conventional information recording medium for mark position recording,
the size of a recorded portion (amorphous area) is not larger than that of
a non-recorded portion (crystalline area) on a recording layer. On the
other hand, in an information recording medium for mark length recording,
the size of a recorded portion is larger than that of the recorded portion
obtained in the mark position recording. For example, assume that the
diameter of the recording mark is 0.78 .mu.m, and that recording is
performed at the same density in mark position recording and mark length
recording. In this case, a ratio of the area of the recorded portion to
the area of the non-recorded portion on the recording layer in the mark
position recording is 26%, and a ratio of the area of the recorded portion
to the area of the non-recorded portion on the recording layer in the mark
length recording is 44%. When these recording methods are applied to a
conventional information recording medium in which recording is performed
such that the reflectance decreases, as the ratio of the area of the
recorded portion to the area of the non-recorded portion is larger, an
average reflectance obtained during a reproducing operation is lower than
that obtained before a recording operation is performed.
In the mark position recording, even when recording is performed such that
the reflectance decreases, a certain amount of reflected light can be
obtained, and focusing and tracking operations are performed by a normal
optical disk drive to reproduce a signal. However, in an information
recording medium in which recording is performed such that the reflectance
decreases, when recording marks are formed at a high density in mark
length recording in accordance with high-density recording, a ratio of the
area of the recorded portion to the entire area of the recording layer
increases in a reproducing operation. For this reason, the average
reflectance decreases to 60% or less of the original average reflectance.
In general, in order to stably perform focusing and tracking operations,
at least a reflectance of about 10% is required. Therefore, in this case,
an amount of reflected light required for the focusing and tracking
operations cannot be obtained. In order to increase the reflectance, the
thickness of the second protective layer must be increased. In this case,
a large reflectance change amount cannot be obtained.
When an information recording medium in which recording is performed such
that the reflectance decreases is used, if light does not escape from the
lower surface of the reflecting layer, the absorbance of the recorded
portion increases, and the absorbance of the non-recorded portion
decreases accordingly. For this reason, an absorbance obtained when a new
mark is overwritten in the recorded portion is different from an
absorbance obtained when a new mark is overwritten in the non-recorded
portion, and the rates of increase in temperature of the recorded and
non-recorded portions of the recording layer are different from each other
during a recording operation. In addition, latent heat is required to melt
the non-recorded portion because the state of the non-recorded portion is
a crystalline state. For this reason, when the recorded and non-recorded
portions are heated by the same laser power, the difference between the
rates of temperature increase in temperature further increases. For this
reason, the sizes of formed recording marks vary depending on areas in
which the recording masks are formed. Therefore, a recording scheme in
which the edge portions of recording marks have information is used, the
edge portions fluctuate depending on their positions on the recording
layer.
SUMMARY OF THE INVENTION
The present invention is made in consideration of the above circumstances,
and has as its object to provide an information recording medium capable
of stably performing focusing and tracking operations and a recording
method using this information recording medium.
It is another object of the present invention to provide an information
recording medium comprising a metal layer formed on a transparent
substrate, a protective layer formed on the metal layer, a recording layer
formed on the metal layer and having optical characteristics changed by
radiating a recording light beam on the recording layer, and a reflecting
layer formed on the recording layer, wherein a reflectance obtained after
a recording operation is performed is higher than a reflectance obtained
before the recording operation is performed, and to provide a recording
method using this information recording medium.
According to the present invention, there is provided an information
recording medium comprising a substrate, a metal layer formed on the
substrate, and a recording layer formed on the metal layer and being
formed a recorded portion and a non-recorded portion by changing optical
characteristics by radiating a recording light beam, wherein the recording
layer contains GeSbTe, a reflectance of the recorded portion of the
recording layer is higher than that of the non-recorded portion, and a
reflectance of the non-recorded portion is not less than 10%.
According to the present invention, there is provided an information
recording medium comprising: a transparent substrate; a metal layer formed
on the transparent substrate and having a thickness of 80 to 200 .ANG.; a
first protective layer formed on the metal layer and having a thickness of
1,200 to 1,600 .ANG. or 3,100 to 3,500 .ANG.; a recording layer formed on
the first protective layer having a thickness of not more than 350 .ANG.,
having optical characteristics changed by radiating a recording light beam
on the recording layer, and including GeSbTe; a second protective layer
formed on the recording layer and having a thickness of 200 to 1,600 .ANG.
or 1,900 to 3,400 .ANG.; and a reflecting layer formed on the second
protective layer and having a thickness of not less than 1,000 .ANG..
The information recording medium according to the present invention is
characterized in that, a semitransparent metal layer is interposed between
the substrate and the first protective layer in a conventional layer
arrangement (substrate/first protective layer/second protective
layer/reflecting layer), and the interferences of the interfaces between
these layers and the interference of the interface between the substrate
and the first protective layer are utilized, thereby obtaining a layer
arrangement in which recording is performed such that a reflectance
increases during a recording operation unlike the conventional layer
arrangement.
In this manner, even when mark length recording is performed, the
reflectance of the recorded portion increases, a sufficient amount of
reflected light can be obtained, and focusing and tracking operations can
be stably performed. In addition, the recorded portion has a low
absorbance, and the non-recorded portion has a high absorbance. For this
reason, the difference between the rates of increase in temperature
obtained when new marks are respectively overwritten in the recorded and
non-recorded portions can be corrected, and recording marks having the
same size can be formed. Therefore, recording in which a variation in edge
is suppressed can be performed.
Additional objects and advantages of the invention will be set forth in the
description which follows, and in part will be obvious from the
description, or may be learned by practice of the invention. The objects
and advantages of the invention may be realized and obtained by means of
the instrumentalities and combinations particularly pointed out in the
appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part
of the specification, illustrate a presently preferred embodiment of the
invention and, together with the general description given above and the
detailed description of the preferred embodiment given below, serve to
explain the principles of the invention.
FIG. 1 is a sectional view showing an information recording medium
according to an embodiment of the present invention;
FIG. 2 is a graph showing the reflectances of recorded and non-recorded
portions and a reflectance change amount when the thickness of a first
protective layer is changed in the information recording medium according
to the present invention;
FIG. 3 is a graph showing the reflectances of the recorded and non-recorded
portions and a reflectance change amount when the thickness of a metal
layer is changed in the information recording medium according to the
present invention;
FIG. 4 is a graph showing the reflectances of the recorded and non-recorded
portions and a reflectance change amount when the thickness of a second
protective layer is changed in the information recording medium according
to the present invention;
FIG. 5 is a graph showing the reflectances of the recorded and non-recorded
portions and a reflectance change amount when the thickness of a recording
layer is changed in the information recording medium according to the
present invention;
FIG. 6 is a graph showing a combination between the thickness of the first
protective layer and the thickness of the second protective layer to
obtain the effect of the present invention;
FIG. 7 is a view for explaining an apparatus for recording/reproducing
information using the information recording medium according to the
present invention; and
FIG. 8 is a view for explaining a reproduced signal in an information
recording medium in which information is recorded using the apparatus
shown in FIG. 7.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
An embodiment of the present invention will be described below with
reference to the accompanying drawings.
FIG. 1 is a sectional view showing an information recording medium
according to an embodiment of the present invention. In FIG. 1, reference
numeral 10 denotes a transparent substrate. A semitransparent metal layer
11 is formed on the transparent substrate 10. A protective layer 12, a
recording layer 13, a protective layer 14, and a reflecting layer 15 are
sequentially stacked on the metal layer 11.
As the material of the transparent substrate 10, glass or a plastic
material such as an acrylic resin or a polycarbonate resin can be used.
The thickness of the transparent substrate 10 is about 0.5 to 1.5 mm. As
the material of the metal layer 11, a metal such as Au, Ag, Cu, or Cr or
an alloy containing these metals can be used. As the material of the first
and second protective layers 12 and 14, ZnS, SiO.sub.2, Al.sub.2 O.sub.3,
or a mixture thereof can be used. As the material of the recording layer
13, a chalcogenite such as GeSbTe can be used. As the material of the
protective layer 14, Al, Au, or an alloy using Al or Au as a base material
and containing Ti, Mo, Zr, or Cr can be used. The thickness of the
protective layer 14 is preferably set to be 1,000 .ANG. or more because
the protective layer 14 is used not only to obtain optical reflection but
also to effectively disperse heat generated by the recording layer 13.
Note that each layer can be formed by deposition such as vacuum deposition
or sputtering.
FIG. 2 is a graph showing the reflectances of recorded and non-recorded
portions and a reflectance change amount when the thickness of the first
protective layer 12 is changed in the information recording medium
according to the present invention.
In this case, an Au layer having a thickness of 100 .ANG. is used as the
metal layer, a GeSbTe layer having a thickness of 200 .ANG. is used as the
recording layer, a ZnS: SiO.sub.2 layer having a thickness of 500 .ANG. is
used as the second protective layer, and an Al layer having a thickness of
2,000 .ANG. is used as the reflecting layer.
Since incident light from the transparent substrate causes multiple
reflection at the interfaces between the layers, the rates of change in
reflectance varies depending on the thickness of the first protective
layer. Referring to FIG. 2, when the thickness of the first protective
layer falls within a range of 1,000 to 1,700 .ANG. or a range of 2,800 to
3,600 .ANG., the reflectance increases during a recording operation. In
this case, when the thickness of the first protective layer is set to be
1,500 .ANG. or 3,400 .ANG., a reflectance change amount becomes a maximum
of 22%. In this case, since the reflectance of the non-recorded portion is
20%, the reflectance of the recorded portion increases after the recording
operation is performed. Therefore, focusing and tracking operations can be
stably performed, and a maximum reflectance change amount can be obtained.
An appropriate thickness of the first protective layer falls within a
range of 1,200 to 1,600 .ANG. or a range of 3,100 to 3,500 .ANG. in which
half of the maximum reflectance change amount, i.e., 22%, is obtained.
FIG. 3 is a graph showing the reflectances of the recorded and non-recorded
portions and a reflectance change amount when the thickness of the metal
layer consisting of Au is changed in the information recording medium
having the above arrangement. As is apparent from FIG. 3, when the
thickness of the metal layer exceeds 40 .ANG., the reflectance of the
recorded portion is higher than that of the non-recorded portion, and the
reflectance increases during a recording operation. This is because, when
the thickness of the metal layer exceeds 40 .ANG., an interference effect
at the interface between the transparent substrate and the metal layer
appears. In addition, when the thickness of the metal layer exceeds 80
.ANG., the reflectance of the non-recorded portion exceeds 10% and
monotonously increases.
On the other hand, in consideration of a reflectance change amount, a
maximum reflectance change amount can be obtained when the thickness of
the metal layer is 120 .ANG.. However, the thickness of the metal layer
exceeds 200 .ANG., the reflectance change amount become 50% or less of the
maximum reflectance change amount. For this reason, when the thickness of
the metal layer is 80 to 200 .ANG., the reflectance of the non-recorded
portion is 10% or more, focusing and tracking operations can be stably
performed, and a large reflectance change amount can be obtained. In this
case, the birefringence of Au is 0.15-5.3i with respect to a laser beam
having a wavelength of 690 nm. Therefore, as the material of the metal
layer, not only Au but also a metal having the same birefringence as that
of Au can be used. As the metal, Ag, Cu, Cr, or an alloy containing these
metals can be used.
FIG. 4 is a graph showing the reflectances of the recorded and non-recorded
portions and a reflectance change amount when the thickness of the second
protective layer is changed in the information recording medium having the
above arrangement. As is apparent from FIG. 4, a sufficient reflectance
change amount in which the reflectances increase in almost all areas
during a recording operation with respect to the thickness of the second
protective layer can be obtained. When the thickness of the second
protective layer falls within a range of 200 to 1,600 .ANG. or a range of
1,900 to 3,400 .ANG., a reflectance change amount of 20% or more and a
reflectance of 10% or more in the non-recorded portion can be obtained. In
this manner, in the information recording medium according to the present
invention, even if the thickness of the second protective layer is 200
.ANG., a sufficient reflectance change amount can be obtained. For this
reason, rapid cooling which is performed by modulation of a laser power
and which is a problem in a conventional information recording medium can
be controlled.
FIG. 5 is a graph showing the reflectances of the recorded and non-recorded
portions and a reflectance change amount when the thickness of the
recording layer is changed in the information recording medium having the
above arrangement. As is apparent from FIG. 5, when the thickness of the
recording layer is 500 .ANG. or less, a change in reflectance can be
obtained. However, in consideration of both the reflectance of the
non-recorded portion and the change in reflectance, the thickness of the
recording layer is preferably set to be 350 .ANG. or less.
In consideration of the characteristics of each layer shown in FIGS. 2 to
5, the thickness of each layer is set such that the reflectance obtained
after a recording operation is performed is higher than the reflectance
before the recording operation is performed. That is, the absolute
thicknesses of the metal layer 11 and the recording layer 13 are defined
as is apparent from the FIGS. 3 and 5, respectively. The thickness of the
reflecting layer 15 must be set to be a thickness, e.g., 1,000 .ANG. or
more, at which the reflecting layer 15 does not substantially transmit
light.
On the other hand, when the thicknesses of the first and second protective
layers 12 and 14 increase, as is apparent from FIG. 4, an area having a
thickness value at which a reflectance obtained after a recording
operation is performed is higher than a reflectance obtained before the
recording operation is performed and an area having a thickness value at
which the reflectance obtained after the recording operation is performed
is lower than the reflectance obtained before the recording operation is
performed periodically appear. For this reason, a combination of the
thicknesses of the protective layers 12 and 14 must be appropriately
selected such that the reflectance obtained after the recording operation
is performed is higher than the reflectance obtained before the recording
operation is performed. For example, when the thicknesses of the metal
layer, the recording layer, and the reflecting layer are set to be 100
.ANG., 200 .ANG., and 2,000 .ANG., respectively, a combination of the
thicknesses of the first and second protective layers 12 and 14 in which
the reflectance obtained after the recording operation is performed is
higher than the reflectance before the recording operation is performed by
a change in reflectance of more than 10% is within a hatched area shown in
FIG. 6. Therefore, when the thicknesses of the first and second protective
layers 12 and 14 are set within the hatched area shown in FIG. 6, an
information recording medium in which the reflectance obtained after the
recording operation is performed is higher than the reflectance obtained
before the recording operation is performed can be manufactured.
In this embodiment, a calculation result obtained using a laser beam having
a wavelength of 690 nm is exemplified. For this reason, when the
wavelength of the laser beam used for a recording operation changes, the
thickness of each layer is appropriately changed in accordance with the
wavelength. In addition, the optimal thickness of each layer is changed in
accordance with the shape of a groove, formed in the transparent
substrate, for tracking a light beam. However, in any case, when the
thickness of each layer is set such that the reflectance increases during
the recording operation and the reflectance of the non-recorded portion is
10% or more, this embodiment does not depart from the spirit and scope of
the present invention.
A case wherein information recording is performed using such an information
recording medium will be described below. As an information recording
medium used in this case, an optical disk obtained as follows was used.
That is, an Au layer as a metal layer having a thickness of 100 .ANG.. a
ZnS: SiO.sub.2 layer having a thickness of 1,400 .ANG. and serving as a
first protective layer, a GeSbTe (composition: atomic ratio of 2:2:5)
layer having a thickness of 300 .ANG. and serving as a recording layer, a
ZnS: SiO.sub.2 layer having a thickness of 300 .ANG. and serving as a
second protective layer, and an Al layer having a thickness of 2,000 .ANG.
and serving as a reflecting layer were sequentially formed by vacuum
sputtering on a polycarbonate disk having a groove, a diameter of 90 mm,
and a thickness of 1.2 mm.
FIG. 7 is a view for explaining an apparatus for recording/reproducing
information using the information recording medium according to the
present invention. Referring to FIG. 7, an optical disk 21 is rotated by a
motor 22 at a predetermined speed. This motor 22 is controlled by a motor
control circuit 38. An optical head 23 performs recording/reproducing
operations of information on the optical disk 21. This optical head 23 is
fixed to a drive coil 33 constituting the movable portion of a linear
motor 51. This drive coil 33 is connected to a linear motor control
circuit 37. A permanent magnet (not shown) is arranged at the fixed
portion of the linear motor 51. When the drive coil 33 is excited by the
linear motor control circuit 37, the optical head 23 moves at an almost
constant speed in the radial direction of the optical disk 21.
In the optical head 23, an objective lens 26 is held by a wire or leaf
spring (not shown), and this objective lens 26 is moved by a drive coil 25
in a focusing direction (the direction of the optical axis of the lens)
and can be moved by a drive coil 24 in a tracking direction (the direction
perpendicular to the optical axis of the lens).
A laser beam generated by a laser diode (semiconductor laser oscillator) 29
driven by a laser control circuit 34 is radiated on the optical disk 21
through a collimator lens 31a, a half prism 31b, and the objective lens
26. The beam reflected by the optical disk 21 is guided to a photodetector
28 through the objective lens 26, the half prism 31b, a condenser lens
30a, and a cylindrical lens 30b. This photodetector 28 is constituted by
four divided photodetective cells 28a, 28b, 28c, and 28d.
An output signal from the photodetective cell 28a of the photodetector 28
is supplied to one terminal of each of adders 50a and 50c through an
amplifier 32a, an output signal from the photodetective cell 28b is
supplied to one terminal of each of adders 50b and 50d through an
amplifier 32b, an output signal from the photodetective cell 28c is
supplied to the other terminal of each of the adders 50b and 50c through
an amplifier 32c, and an output signal from the photodetective cell 28d is
supplied to the other terminal of each of the adders 50a and 50d through
an amplifier 32d. An output signal from the adder 50a is supplied to the
inverting input terminal of a differential amplifier OP1, and an output
signal from the adder 50b is supplied to the non-inverting input terminal
of the differential amplifier OP1. In this manner, the differential
amplifier OP1 supplies a track difference signal to a tracking control
circuit 36 in accordance with the difference between the outputs from the
adders 50a and 50b. This tracking control circuit 36 forms a track drive
signal in accordance with the track difference signal supplied from the
differential amplifier OP1.
The track drive signal output from the tracking control circuit 36 is
supplied to the drive coil 24 located in the tracking direction. The track
difference signal used in the tracking control circuit 36 is supplied to
the linear motor control circuit 37. The linear motor control circuit 37
applies a voltage corresponding to a moving speed to a drive coil
(conductive line) 33 in the linear motor 51 (to be described later) in
accordance with the track difference signal from the tracking control
circuit 36 and a moving control signal from a CPU 43.
In the linear motor control circuit 37, a speed detection circuit (not
shown) is arranged. This speed detection circuit detects a relative speed
between the drive coil 33 and a magnetic member (not shown), i.e., the
moving speed of the linear motor 51, using an electrical change in the
drive coil 33 occurring when the drive coil 33 in the linear motor 51
crosses a magnetic flux generated by the magnetic member.
An output signal from the adder 50c is supplied to the inverting input
terminal of a differential amplifier OP2, and an output signal from the
adder 50d is supplied to the non-inverting input terminal of the
differential amplifier OP2. In this manner, the differential amplifier OP2
supplies a signal related to a focal point to a focusing control circuit
35 in accordance with the difference between the outputs from the adders
50c and 50d. An output signal from the focusing control circuit 35 is
supplied to the focusing drive coil 25 to control the drive coil 25 such
that a laser beam is always just focused on the optical disk 21.
A sum signal of the outputs from the photodetective cells 28a to 28d of the
photodetector 28 obtained when the focusing and tracking operations are
performed as described above, i.e., the output signals from the adders 50a
and 50b, are changed depending on a change in reflectance represented by a
pit (recorded information) formed in the track. These signals are supplied
to a signal processing circuit 39. In this signal processing circuit 39,
recorded information and address information (track number, sector number,
and the like) are reproduced.
The laser emission output from the laser diode 29 is monitored by a
photodiode 52, converted into an electrical signal, and fed back to the
laser control circuit 34, thereby stabilizing the laser emission output
from the laser diode 29. A laser emission ON/OFF signal and a recording
data signal from a recording data signal control circuit 53 constituted by
a microprocessor and the like are input to the laser control circuit 34. A
high-frequency current (to be described later) output from a
high-frequency current generating circuit 54 through a coupling capacitor
55 is superposed on a drive current output from the laser control circuit
34.
In this apparatus, a D/A converter 42 used for performing
transmission/reception of information between the focusing control circuit
35, the tracking control circuit 36, the linear motor control circuit 37,
and the CPU 43 is arranged. The tracking control circuit 36 causes the
objective lens 26 to move in accordance with a track jump signal supplied
from the CPU 43 through the D/A converter 42 to make a light beam to move
by one track. The laser control circuit 34, the focusing control circuit
35, the tracking control circuit 36, the linear motor control circuit 37,
the motor control circuit 38, the signal processing circuit 39, the
recording data signal control circuit 53, the high-frequency current
generating circuit 54, and the like are controlled by the CPU 43 through a
bus line 40. The CPU 43 performs a predetermined operation in accordance
with a program stored in a memory 44.
In the apparatus having the above arrangement, an optical disk having a
recording layer crystallized by radiating an argon laser beam on the
recording layer in advance was arranged, and signals were recorded while
the motor was rotated. At this time, a rotational speed was set to be
3,000 rpm. As a recording signal, random data (marks having different
lengths) having a 1,7 RLL (Run Length Limited) code in which the length of
a shortest mark was set to be 1.6 .mu.m. As a result, focusing and
tracking operations could be stably performed after and before a recording
operation was performed. At this time, the reflectance of a non-recorded
portion was 13%, and the reflectance of a recorded portion was 35%.
A reproduced signal obtained at this time is shown in FIG. 8. The
intermediate point of a signal amplitude is used as the slice level of
digital data, and digital data is formed while the digital data is
compared with a signal. When a digital signal actually reproduced was
compared with the random data having a 1,7 RLL code and used in the
recording operation, the random data completely coincided with the digital
signal. Therefore, it was confirmed that data having this code could be
recorded/reproduced.
As has been described above, an information recording medium according to
the present invention comprises a metal layer formed on a transparent
substrate, a recording layer formed on the metal layer and having optical
characteristics changed by radiating a recording light beam on the
recording layer, and a reflecting layer formed on the recording layer. A
reflectance obtained after a recording operation is performed increases.
For this reason, even when mark length recording is performed, a
sufficient amount of reflected light can be obtained, and
focusing/tracking operations can be stably performed. In addition, mark
length recording/reproducing can be stably performed using the information
recording medium.
Additional advantages and modifications will readily occur to those skilled
in the art. Therefore, the invention in its broader aspects is not limited
to the specific details, representative devices, and illustrated examples
shown and described herein. Accordingly, various modifications may be made
without departing from the spirit or scope of the general inventive
concept as defined by the appended claims and their equivalents.
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