Stock material or miscellaneous articles – Circular sheet or circular blank
Reexamination Certificate
2000-03-20
2002-06-25
Mulvaney, Elizabeth Evans (Department: 1774)
Stock material or miscellaneous articles
Circular sheet or circular blank
C428S064200, C430S270110
Reexamination Certificate
active
06410116
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to an optical information medium such as read only optical disks and optical recording disks and its fabrication process.
In recent years, optical information media such as read only optical disks and optical recording disks have been required to have ever-higher recording densities and, hence, ever-higher capacities so as to record or store an enormous amount of information such as moving image information. To meet this requirement, media having such high recording densities are now under extensive and intensive research and development.
According to one of approaches proposed so far to this end, recording and reproducing wavelengths are shortened while the numerical aperture (NA) of an objective in a recording and reproducing optical system is increased, thereby reducing the diameter of recording and reproducing laser beams, as typically practiced in the case of a digital versatile disk or DVD. When the recording and reproducing wavelength is decreased from 780 nm down to 650 nm and the NA is increased from 0.45 up to 0.6, the recording capacity of the DVD is 4.7 GB/surface or 6 to 8 times as large as that of a CD.
As the NA increases, however, the tilt margin decreases. The tilt margin is the tolerance of the tilt of an optical recording medium with respect to an optical system, and is determined by the NA. Here let &lgr; be a recording and reproducing wavelength and t be the thickness of a transparent substrate on which recording and reproducing light is incident. Then, the tilt margin is proportional to:
&lgr;/(t·NA
3
)
As the optical recording medium tilts with respect to a laser beam, wavefront aberration (coma) occurs. Here let n denote the refractive index of the substrate and &thgr; stand for the angle of tilt. Then, the wavefront aberration coefficient is given by:
(½)·t·{n
2
·sin &thgr;·cos &thgr;}·NA
3
/(n
2
−sin
2
&thgr;)
−5/2
From these expressions, it is understood that the thickness t of the substrate should preferably be reduced to increase the tilt margin and prevent the occurrence of coma. In a DVD, indeed, the tilt margin is ensured by making the thickness of the substrate about half (ca. 0.6 mm) the thickness (ca. 1.2 mm) of the substrate of a CD. On the other hand, the thickness variation margin for the substrate is given by:
&lgr;/NA
4
When there a thickness variation in the substrate, another wavefront aberration (spherical aberration) occurs. Here let &Dgr;t be the thickness variation of the substrate. Then, the spherical aberration coefficient is given by:
{(n
2
−1)/8n
3
}·NA
4
·&Dgr;t
From these expressions, it is understood that to reduce the spherical aberration produced with an increasing NA, it is required to reduce the thickness variation as much as possible. For instance, &Dgr;t is of the order of ±100 &mgr;m in the case of a CD whereas &Dgr;t is limited to ±30 &mgr;m in the case of a DVD.
To record moving images of higher quality over an extended period of time, a structure enabling a substrate to become thinner has been put forward in the art. According to this structure, a substrate having an ordinary thickness is used as a supporting substrate for maintaining rigidity. Pits or a recording layer are formed on the surface of the substrate. A light-transmitting layer of about 0.1 mm in thickness is provided as a thin substrate on the recording layer, so that recording and reproducing light can be incident on the recording layer through the light-transmitting layer. With this structure, it is possible to achieve an ever-higher NA and, hence, an ever-higher recording density, because the substrate can be made much thinner than could be possible with conventional structures.
However, it is very difficult to form the light-transmitting layer used for this structure, using resin injection molding. To eliminate such difficulty, it has been proposed to form such a light-transmitting layer by spin-coating of an ultraviolet-curing resin, as typically disclosed in JP-A 9-161333. In JP-A 10-269624, it is proposed to coat a dispersion of spacer particles in a photo-curing resin on a substrate and press the dispersion down on the substrate with a plate material, thereby forming a light-transmitting layer of uniform thickness. In JP-A 10-283683, it is proposed to bond an ultraviolet-curing resin onto a light-transmitting sheet.
When a light-transmitting layer is formed by the processes set forth in the aforesaid publications, however, a medium warping problem arises due to shrinkage upon curing of the resin forming part of the light-transmitting layer. When the photo-curing resin is configured into a film of about 0.1 mm in thickness, it is difficult to achieve uniform curing in the thickness direction. As a result, the light-transmitting layer lacks optical uniformity, and the reliability of the medium is likely to become low due to the presence of uncured monomers. According to the process shown in the aforesaid JP-A 10-283683, the ultraviolet-curing resin layer is thinner than those obtained by other processes because the ultraviolet-curing resin is used as an adhesive layer, and so the medium is less susceptible to warpage. However, the distortion by shrinkage of the resin upon ultraviolet curing leads to another problem that the index of birefringence of the light-transmitting sheet becomes large.
SUMMARY OF THE INVENTION
An object of the present invention is to provide an optical information medium comprising a supporting substrate, an information-recording surface provided on a surface of said supporting substrate and a light-transmitting layer provided on said information-recording surface and formed of a resin, wherein said light-transmitting layer is allowed to have a uniform thickness so that optical heterogeneity of the light-transmitting layer in its thickness direction can be reduced, and any warping of the optical information medium is prevented.
Such an object is achievable by the inventions recited below as (1) to (4).
(1) An optical information medium comprising a supporting substrate, an information-recording surface provided on the supporting substrate and a light-transmitting layer provided on the information-recording surface, with recording light and/or reproducing light incident on the information-recording surface through the light-transmitting layer, wherein:
said light-transmitting layer is obtained by curing a resin layer containing an ultraviolet-curing cationic resin.
(2) The optical information medium according to any one of (1) above, wherein said light-transmitting layer has a thickness of 30 to 300 &mgr;m.
(3) A process of fabricating an optical information medium comprising a supporting substrate, an information-recording surface provided on the supporting substrate and a light-transmitting layer provided on the information-recording surface, with recording light and/or reproducing light incident on the information-recording surface through the light-transmitting layer, wherein said light-transmitting layer is formed by repeating a cycle of resin coating and resin curing or drying a plurality of times.
(4) The fabrication process according to (3) above, wherein said resin contains an ultraviolet-curing cationic resin.
REFERENCES:
patent: 5573831 (1996-11-01), Suzuki
patent: 5599649 (1997-02-01), Shinkai
patent: 6278683 (2001-08-01), Hayashi
patent: 9-161333 (1997-06-01), None
patent: 10-269624 (1998-10-01), None
patent: 10-283683 (1998-10-01), None
Mulvaney Elizabeth Evans
Oblon, Spivak, McClelland, Maier & Neustradt, P.C.
TDK Corporation
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