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Claims  |
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We claim:
1. An optical memory card for optical information comprising,
a self-supporting, wallet size, planar plastic base,
a vacuum or vapor deposited continuous metallic reflective layer over said
plastic base,
a planar optical storage layer disposed over the metallic layer, said
optical storage layer having a planar crust of irregular, non-filamentary
oblong black silver particles substantially within the top one-half micron
of the layer distal to the metallic layer, said optical storage layer
having a substantially clear gelatin below the crust.
2. The optical memory card of claim 1 further comprising a film substrate
layer disposed over said base in intimate contact therewith in planar
relation, said metallic layer deposited on said film substrate layer.
3. The optical memory card of claim 1 wherein said metallic layer is
selected from the group consisting of gold, silver, aluminum, platinum,
rhodium, copper and alloys thereof.
4. The optical memory card of claim 1 wherein a transparent, protective,
planar layer is disposed over said optical storage layer.
5. The optical memory card of claim 1 wherein said optical storage layer
contains prerecorded information.
6. The optical memory card of claim 1 wherein said optical storage layer
contains prerecorded information and laser written data.
7. A double-sided optical memory card for optical information comprising,
a self-supporting, wallet-size, optically transparent planar plastic base,
a first planar optical storage layer disposed over said plastic base, said
optical storage layer having a crust of irregular, non-filamentary oblong
black silver particles substantially within one-half micron of the layer
proximal to the base and having a substantially clear gelatin below the
crust,
a first vapor or vacuum deposited metallic continuous reflective layer
disposed on said gelatin layer,
a first planar support layer disposed over said molecular metallic layer,
said support layer having opposed planar surfaces, including a lower
surface proximate said plastic base and an upper surface distal to said
plastic base,
a second planar support layer, substantially identical to said first
support layer and adhered to the upper surface thereof,
a second vapor or vacuum deposited metallic continuous reflective layer
disposed over said second planar transparent support layer,
a second planar optical storage layer disposed over the upper surface of
said second planar transparent support layer, said optical layer having a
planar crust of irregular, non-filamentary oblong black silver particles
substantially within the top one-half micron of the layer distal to the
base and having a substantially clear gelatin below the crust, and
a transparent, protective, planar layer disposed over said second storage
layer,
each of said optical storage layers having been previously exposed at
actinic wavelength and developed and fixed to be a substantially dark very
thin black silver layer, but having an imagewise exposure pattern of clear
marks with underlying high reflectivity metallic layer for light at the
reducing wavelength.
8. The optical memory card of claim 7 wherein said metallic layer material
is selected from the group consisting of gold, silver, aluminum, platinum,
rhodium, copper and alloys thereof.
9. The data card of claim 7 wherein said optical storage layers contain
prerecorded information.
10. The data card of claim 7 wherein said optical storage layers contain
prerecorded information and laser written data.
11. A method for making an optical information memory card comprising,
depositing a continuous vacuum or vapor metallic layer over a
self-supporting, planar plastic base,
disposing a planar photosensitive emulsion layer over said metallic layer,
developing and fixing only a planar crust of said emulsion to a
substantially dark thin layer of irregular, non-filamentary silver
particles with a substantially clear gelatin layer beneath said crust, and
disposing a transparent, planar protective layer over said planar crust.
12. The method of claim 11 further defined by
making an imagewise exposure of marks representing control indicia or data,
said exposure made in said photosensitive emulsion layer with radiation,
and
developing and fixing said exposure pattern of image marks being
substantially clear revealing an underlying reflectivity in the metallic
layer when illuminated by light.
13. The method of claim 11 wherein said photosensitive emulsion layer is
composed of a silver chloride emulsion.
14. The method of claim 11 wherein said photosensitive emulsion layer is
composed of a silver bromide emulsion and developing said emulsion is
performed with a chemical developer containing an organic antifoggant.
15. A method of making an optical information memory card comprising,
depositing a continuous vacuum or vapor metallic layer onto a transparent
film substrate layer,
disposing a planar photosensitive emulsion layer over said metallic layer,
developing and fixing only a planar crust of said emulsion to be a
substantially dark thin layer of irregular, non-filamentary silver
particles with a substantially clear gelatin layer beneath said crust,
said film substrate layer, said metallic layer and said developed and
fixed emulsion layer forming a laser recordable optical storage film,
disposing said developed optical storage film over a self-supporting,
wallet-size, planar plastic base, and
disposing a transparent, planar protective layer over said planar crust.
16. The method of claim 15 further comprising,
making an imagewise exposure of marks representing control indicia or data,
said exposure made in said photosensitive emulsion layer with radiation,
and
developing and fixing said exposure pattern of image marks being
substantially clear revealing an underlying reflectivity in the metallic
layer when illuminated by light, said developing and fixing occurring
prior to disposing said developed optical storage film over said plastic
base.
17. A system for recording data by means of a laser comprising,
an optical memory card having a self-supporting, wallet-size planar base,
and at least one optical storage layer disposed on said base, each said
optical storage layer having a planar crust of irregular nonfilamentary
oblong black silver particles substantially within one-half micron of a
surface of said storage layer and substantially clear gelatin behind the
crust, a continuous reflective metallic layer being disposed behind the
gelatin, the optical storage layer being laser recordable in place on said
card producing reflective data spots revealing an underlying reflectivity
of the metallic layer against a background field of said crust, the
optical reflective contrast ratio of the data spots to the surrounding
field being at least 1.2 to one,
laser means having at least one beam disposed in laser writing relation
with respect to said at least one optical storage layer for writing data
in a plurality of paths,
light detector means in reading relation with respect to at least one said
optical storage layer for reading said paths, and
means for providing relative motion between said laser beam and said card
for following said paths. |
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Claims |
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Description |
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DESCRIPTION
1. Technical Field
The invention relates to optical data storage and in particular to a card
having a high contrast medium adapted for both prerecorded and user
recorded data.
2. Background Art
In U.S. Pat. No. 4,239,338, Borrelli et al. teach an optical information
storage medium comprising a glass substrate, a 1000 Angstrom thick silver
layer applied to the substrate, an oxide layer deposited over the silver
layer and a multilayer additively colored AgC1/PbO film applied over the
oxide layer. The film is optically bleachable using visible light to
produce a dichroic, birefringent image. The image is read in infrared
light, since the film is transparent at infrared wavelengths down to the
silver layers. The silver layer permits reading and writing in the
reflective mode. The film should have a thickness not exceeding about two
microns to permit high spot resolution.
In U.S. Pat. No. 4,278,756, Bouldin et al. teach a reflective laser
recording and data storage medium formed from a photosensitive
silver-halide emulsion. The emulsion is exposed and developed using a
negative silver diffusion transfer process to make the film surface shiny
compared to data spots which are clear or dark. The shiny surface may be
above or below the main body of the emulsion depending on whether the
reading light is to be introduced from above or from below through a clear
substrate.
In U.S. Pat. No. 4,542,288, Drexler teaches use of a data card having the
media of the kind described in U.S. Pat. No. 4,278,756. Certain
information, such as servo tracks and data base information, can be
prerecorded photolithographically.
In reflective optical data storage media, high optical contrast between
data spots and the media background and sharply defined data spots are
necessary for resolving data, particularly where data spots are small,
i.e. ten microns or less in size. For inexpensive optical memory cards it
is also desirable that the optical storage and recording media provide
several capabilities in addition to high contrast and high resolution. The
media should record with a laser beam, it should be capable of
pre-recording servo track guides, timing marks or other formatting indicia
and data during card manufacturing and it should be capable of laser
recording formatting patterns on a finished optical memory card. An
optical memory card is valuable with data bits as large as three to ten
microns while optical disks require data bits one micron or smaller to be
valuable. Thus technical approaches can be used with cards that cannot be
used with disks.
An object of this invention was to achieve adequate recording sensitivity
for laser written data on reflective optical storage media applicable to
optical memory cards, while providing for optical photolithographic
pre-recording of track formats and other data prior to completion of the
finished card and also providing for laser recording of track formats and
other data on finished optical memory cards.
DISCLOSURE OF THE INVENTION
The above object has been achieved in an optical memory card having a
sensitive laser recording medium which is also suitable for optional
pre-recording of tracking or control information as well as for user data.
The medium is a laser recording material layer having a thin black upper
crust of irregular shaped metal particles forming a dark field with a
clear underlayer and with a thin, reflective metallic layer beneath the
laser sensitive medium, all supported on a card base. Both the crust and
clear underlayer reside in the same layer and thus have the same contour
without any spaces which might lead to refraction. The thin dark crust is
highly absorptive to light so that modification, displacement and/or
agglomeration of the metal particles in the crust by laser light reveals
the shiny reflective metallic underlayer. A principal effect of laser
light on the irregular metal particles of the dark crust is to modify
their shape to that of smooth spheroids with reduced covering power. The
medium is suitable for track and data prerecording because it can be
patterned with information on the surface prior to formation of the dark
field.
The optical storage medium can be made in the following way. A transparent
substrate layer is covered with three layers to form the optical storage
material. Over the substrate layer, a very thin reflective metallic layer
is vacuum or vapor deposited, with a total thickness typically of 100 to
1000 Angstroms. Over this reflective layer is a photographic-type gelatin
layer which has within it a very thin crust of irregular shaped but
nonfilamentary low reflectivity black silver particles. This very thin
layer shall be referred to as the black silver crust. The black silver
crust may be at the upper surface farthest from the reflective layer or it
could be nearer to the reflective layer. This black silver crust may be
patterned with clear areas prior to card manufacture since the black
silver is created by conversion of a photosensitive emulsion by a
photographic exposure and development process.
The developed image pattern transmits light with respect to the surrounding
dark, light-absorptive field. Optical contrast is enhanced by means of the
metallic layer just above the substrate which reflects light back in the
direction from whence it came. The metallic layer may be either gold,
silver, aluminum, platinum, rhodium or copper.
Where two similar optical storage film substrates are processed as
described above, they may be mounted back to back atop a transparent
planar plastic base. This arrangement yields a double sided optical
recording medium in which both sides may be read or written upon
simultaneously.
The very thin black silver reflectively read medium of optical memory cards
of the present invention is a more sensitive laser recording medium
compared to some other recording media. Additionally, optical contrast is
enhanced by means of the underlying reflective layer. The combination of
the thin black silver layer, the gelatin layer and the highly reflective
metal layer form an optical data storage medium for optical memory cards
which has a good laser recording sensitivity, a capability of
pre-recording track formats and other data and a capability of laser
recording track formats and other data on finished cards.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a top plan of a data card of the present invention.
FIG. 2 is an enlarged portion of the data card of FIG. 1 revealing data
spots.
FIG. 3 is a side sectional view of the data card taken along the line 3--3
in FIG. 2.
FIG. 3a is a detail magnified about line 3A--3A in FIG. 3.
FIG. 3b is a side sectional view similar to FIG. 3 of an alternate
embodiment of the data card of the present invention.
FIG. 4 is a side sectional view similar to FIG. 3 showing a third data card
embodiment of the present invention.
FIGS. 5A-5D are top plan views of portions of the data card of FIG. 1
illustrating a method of pre-recording data spots.
FIG. 6 is a side sectional view taken along the line 6--6 in FIG. 5B.
FIG. 7 is a graph showing reflectivity of metallic layers versus
wavelength.
FIG. 8 is a plan view of optical apparatus for reading and writing on a
data card with a laser.
BEST MODE FOR CARRYING OUT THE INVENTION
With reference to FIG. 1, an optical memory card 10 comprises a
self-supporting, wallet-size, planar plastic base 12 with a strip 14 of
recording material disposed thereon. Strip 14 may be either single sided,
as described below with reference to FIGS. 3 and 3b, or double sided, as
described below with reference to FIG. 4. Base 12 may be either
transparent or opaque, but must be transparent where strip 14 is double
sided. Typically, card base 12 is composed of polycarbonate material,
although other suitable materials may also be used. A transparent, planar,
protective layer of scratch resistant material may be disposed over strip
14. A preferred size for card 10 is approximately 54 mm by 85 mm, since
this size is conventional for credit cards and the like, and easily fits
into a wallet. Strip 14 is typically 16 mm to 35 mm wide and extends the
length of the card. These dimensions are not critical however.
With reference to FIG. 2, a magnified view of data stored on the strip 14
may be seen. The border 16, corresponds to dashed line 16 in FIG. 1. Data
spots 18 are seen to be circular and aligned in paths. A second group of
data spots 19 is seen to be aligned in a second path. Spots 18 and 19, as
well as an absence of spots 20, represent data bits. For example, spots 18
and 19 may represent 1's and the absence of spots 20 may represent 0's, or
vice versa. Data spots 18 and 19 are typically reflective, with a
reflectivity at near infrared wavelengths (0.8 to 1.0 microns) generally
in the range of 30% to 50%, while the media background is substantially
less reflective, with a reflectivity at near infrared wavelengths (0.8 to
1.0 microns) generally less than 20% and preferably less than 15%. Optical
reflective contrast between the reflective data spots and the media
background is therefore generally greater than 2 to 1 and preferably at
least 3 to 1 at reading beam wavelengths. A minimum contrast between the
data spots and the background field of 1.2 to 1 is sufficient for reading.
The reflectivity of the data spots is not as high as the 80% to 90%
expected from the reflective metals used since there are usually some
silver particles remaining in the data spot area which absorb some of the
incident and reflected light. The laser recorded spots may be oblong or
circular, while the prerecorded data spots can be oblong, circular or
rectangular. All of the data spots have similar dimensions which are
generally less than about 25 microns in size and preferably less than 10
microns in size. The spacing between paths is not critical, and may even
be adjoining, provided that the optical reading system is able to easily
distinguish between paths.
With reference to FIGS. 3 and 3a, the optical recording media comprises a
film substrate layer 22, a highly reflective metallic layer 24 deposited
on substrate layer 22 and a selected, thin black silver planar crust 26,
generally less than one-half micron thick, within gelatin layer 25. The
latter layer is generally one to six microns thick, disposed on metallic
layer 24, which is generally 100 Angstroms to 1000 Angstroms thick. During
the optical medium manufacturing process the surface of a photosensitive
emulsion raw material, such as AgC1-gelatin emulsion, distal to the
substrate, is developed to dark or black by exposure to actinic radiation
and then to photographic development. Black and clear images can be
created if desired by using a photomask. The exposing image is a pattern,
either control indicia such as tracks or data or both, to be prerecorded.
The depth of the dark layer is typically 0.3 to 0.5 microns. The
undeveloped remainder of the emulsion layer which is essentially gelatin
remains clear. Film substrate layer 22 is disposed over base 12 in
intimate contact therewith in planar relation. Base 12 may be transparent
or opaque. A transparent, planar protective layer 28 may be disposed over
the laser recording layer 26.
Film substrate layer 22 is typically about 100 to 150 microns thick, and
may be composed of polyesters, cellulose acetate, Mylar, or other
materials commonly used as film bases. Metallic layer 24 is typically
composed of either gold, copper, silver, platinum, rhodium or aluminum or
alloys thereof. Gold is preferred because it has a very high reflectivity
at the reading wavelength, at least 90 percent in the near infrared, i.e.
a wavelength longer than 0.8 microns, thereby giving high data contrast.
Also, gold does not react with the photographic chemicals and is
environmentally stable for many years. Gold is also desirable because it
may be used with photographic emulsion layers 25 and 26 with actinic
wavelengths in the blue to green wavelength range (0.4 to 0.6 microns)
with reduced halation effect since gold's reflectivity is about 37% in
this actinic wavelength range and gelatin layer 25 is generally less than
3 microns thick. Silver and aluminum are also preferred materials but care
must be taken that the aluminum does not contaminate the photographic
developer solutions. Copper may also be considered for this application
but is not as chemically stable as the other three materials. Metallic
layer 24 is deposited on film substrate 22 by well-known vapor or vacuum
deposition techniques, for example in coating silicon wafers or magnetic
metallic memory disks. The layer is on the order of 100 to 1,000 Angstroms
thick.
Gelatin layer 25 originally was a silver halide in a gelatin matrix, i.e. a
photographic emulsion layer. The gelatin colloid matrix should be made
from material which is substantially transparent to a read beam wavelength
in the near infrared, and may be further selected to be substantially more
absorptive at an actinic wavelength length thereby enhancing the
antihalation properties of the recording medium during the preformatting
process. Gelatin layer 25 is typically under 3 microns thick, but could be
as thick as 10 microns. The gelatin layer 25 containing crust 26 is shown
having been exposed to actinic radiation through an imagewise exposure
pattern and then developed to be substantially dark only at its surface.
Irregular rings in planar crust 26 represent black irregular oblong silver
particles embedded in the gelatin colloid matrix. The conversion of the
emulsion film into a laser recording material takes place before the film
is incorporated into the card, as described in U.S. Pat. Nos. 4,314,260;
4,298,684; 4,278,758; 4,278,756; and 4,269,917, all assigned to the
assignee of the present invention.
Clear areas 18 represent data spots stored on the media, as for example by
photographic prerecording. Gelatin layer 25 is exposed through an
imagewise exposure pattern to actinic radiation, then developed to be
substantially dark at its surface. Areas 18 not exposed to actinic
radiation are predominantly clear after development and fixing, revealing
an underlying reflectivity in the metallic layer 24 when illuminated by
light of a read beam wavelength, typically in the near infrared. Servo
track lines may be photographically prerecorded as just described. Clear
areas 18 may also represent data spots which have been laser recorded by
modification, displacement, and/or agglomeration of metal particles in the
crust 26 to be predominantly clear, revealing an underlying reflectivity
in the metallic layer 24 when illuminated by light of a read beam
wavelength. The laser recording beam principally heats the thin dark crust
26 and alters the irregular shape of the silver grains so that they become
smooth spheroids. In doing so, the covering power of the silver grains is
reduced so that more light can pass between the particles in the spot of
modified crust into the underlayer. Heating may also cause some
displacement of silver particles away from the spot area, as well as some
agglomeration of separate silver particles. Clear areas 18 are preferably
sharply defined, rather than diffuse or otherwise blurred. The optical
density of background areas 20 at the read beam wavelength of gelatin
layer 25 should be at least 0.5 and preferably greater than 1.0. The
optical density of the spot areas 18 of gelatin layer 25 should be not
more than 0.2 and preferably less than 0.1.
A method for making the optical storage media 14 data card in FIG. 1
comprises depositing metallic layer 24 on film substrate layer 22 by
vacuum or vapor deposition and then applying the thin, planar photographic
emulsion layer 25 over reflective metallic layer 24. The resulting media
may then be prerecorded using the steps of exposure and surface
development described in more detail below with reference to FIGS. 5A-5D
and FIG. 6. Strip 14, seen in FIG. 1, containing prerecorded data is the
result. This strip 14 is then applied to card base 12 by disposing film
substrate layer 22 in intimate adhering planar contact over base 12. A
planar, transparent protective layer 28 may finally be adhered over
gelatin layer 25.
Alternatively, a card may be formed without film substrate layer 22 as seen
in FIG. 3b. Metallic layer 24 may be deposited directly onto card base 12,
and gelatin layers 25, containing the black crust 26, disposed over
metallic layer 24, instead of first forming strip 14 from layers 22, 24,
and 25. Also prerecording of data by exposure, development and fixing may
be performed before of after disposing strip 14 or the individual layers
24 and 25 to base 12. It is preferred to complete processing of strip 14
first since it will be easier to handle when it is no longer
photosensitive.
With reference to FIG. 4, a double sided embodiment of data card 10
comprises a first laser sensitive optical storage layer 30 with a thin
dark crust 31 therein disposed over a self-supporting transparent planar
plastic card base 12, a first vapor or vacuum deposited metallic layer 32
disposed adjacent film substrate layer 34, a second film substrate layer
36 disposed over first substrate layer 36, a second metallic layer 38
disposed over substrate layer 34, and a second laser sensitive optical
storage layer 40 with a thin dark crust 35 therein disposed on metallic
layer 38. The optical storage layers 30 and 40 comprise a thin black or
dark surface area, as mentioned above, with a clear gelatin underlayer. A
transparent protective layer 42 may be disposed over the optical storage
layer 40.
First and second film substrate layers 34 and 36 are substantially similar
to film substrate layer 22 in FIG. 3. Metallic layers 32 and 38 may be
selected from the group consisting of gold, silver, aluminum, platinum,
rhodium, and perhaps copper just as for metallic layer 24 in FIG. 3.
Layers 32 and 38 may be identical or made of different metals. As with
optical storage layer 26 in FIG. 3, each of the thin optical storage
layers 30 and 40 in FIG. 4 was previously created by exposing
photosensitive silver halide emulsion, preferably silver chloride, to
actinic radiation, developing and fixing so that the emulsion is
substantially dark at the emulsion surface, i.e. about 0.3 microns into
the material. The developed emulsion layers 30 and 40 may have an
imagewise exposure pattern of partially clear marks 44 and 18 respectively
representing data bits with underlying high reflectivity in the adjacent
metallic layers 32 and 38 respectively for light of reading wavelength.
The previously developed emulsion layers 30 and 40 may be exposed and
developed either at the same time or separately.
Formation of the optical storage media for the double sided data card in
FIG. 4 may comprise depositing metallic layers 32 and 38 onto film
substrate layers 34 and 36, respectively, by vacuum or vapor deposition.
Then emulsion layers 30 and 40 are disposed on metallic layers 32 and 38,
respectively. Emulsion layers 30 and 40 are then prerecorded as described
in detail below with respect to FIGS. 5A-5D and FIG. 6. Each of the
resulting strips of recording material is substantially similar. Layers
30, 32, and 34 form one strip, while layers 36, 38, and 40 form a second
strip. These optical storage strips are the laser sensitive, but not
photosensitive since all of the silver-halide emulsion was converted to
silver or removed. The two strips are then adhered together, with an upper
surface 46 of first support layer 34 in intimate planar contact with a low
surface 48 of second support layer 36. One of the optical storage layers,
in the present case first optical storage layer 30 is then disposed over
transparent card base 12. A protective layer 42 may be disposed over the
other optical storage layer, here layer 40. Alternatively, each of the
layers may be sequentially disposed over card base 12. Exposure and
development of one or more of the emulsion layers 38 and 40 may be
performed after disposing onto card base 12 but this is more difficult
since the emulsion is photosensitive.
With reference to FIGS. 5A-5D and FIG. 6, a photosensitive medium 50
containing an unexposed photosensitive emulsion layer 66 is disposed for
exposure to actinic radiation. The emulsion layer is preferably a fine
grain silver chloride emulsion in a gelatin matrix. Other silver halides,
such as silver bromide, may be used, but must be developed in a modified
developer solution disclosed below to prevent formation of filamentary
silver. The smaller the grain sizes of the silver-halide emulsion, the
higher the resolution of the final prerecorded product of this invention.
The emulsion grain size should be less than 5% of the recording hole size
for best results, and emulsions with grain size on the order of 0.05
microns are commercially available. Antihalation dyes, also known as
attenuating or accutance dyes, may also be added to the photographic
emulsion to increase the absorptivity of the emulsion at the actinic
wavelength thereby concentrating the exposure to the top surface of the
emulsion. This can help create a thin black recording crust. It can also
reduce any halation effect and give higher resolutions. Such dyes are
commonly used and are water soluble and thus are not present when the
emulsion has been converted to the optical storage media.
If prerecording of track guides or data spots is desired, a shielding mask,
such as mask 52, may be placed over unexposed medium 50. Mask 52 typically
has two degrees of transmissivity to actinic radiation, being
substantially clear over most of its extent, except for an imagewise
pattern of optical dense marks 54, 56, 58, 60. As seen in FIG. 6,
recording medium 50 is exposed with a light source 62 emitting light 64 at
actinic wavelengths. Typically, the actinic light 64 has a wavelength in a
blue-green range of 0.4 to 0.6 microns, although ultraviolet light with
wavelengths less than 0.4 microns may also be used. Light 64 illuminating
mask 52 is transmitted through clear areas 65 of mask 52 to emulsion layer
66, but is blocked by dark marks, such as spots 56, 58, and 60, of mask
52.
Exposure by the emulsion layer 66 to actinic radiation creates a latent
image in which silver halide is activated substantially to saturation
under clear areas 65 of mask 52 and remain substantially unactivated under
dark marks 54, 56, 58 and 60. This latent image is shown in FIG. 5C in
which the exposed photosensitive medium 70 contains an emulsion of
activated silver halide over substantial regions 72 and unactivated silver
halide in spot regions 74, 76, 78 and 80.
Exposed medium 70 is surface developed to produce a medium 82 which is
substantially dark over most of its extent, but having an imagewise
exposure pattern of partially clear marks 84, 86, 88 and 90 with
underlying reflectivity in the metallic layer 68 for light of reading beam
wavelength. Development of the surface layer is surface development
occuring typically within the top 0.3 to 0.5 micron of the emulsion layer
in a plane distal from the substrate. Such development occurs by
contacting the light exposed image layer with a concentrated development
solution for a very short period, before the development solution can
diffuse into the material or by means of a slow-diffusing developer such
as tertiary butylhydroquinone.
Alternatively, a viscous developer thickened with carboxymethylcellulose
may be used. This material is syrupy in consistency and is rolled on. It
may be washed off and development stopped with a spray stop bath. It then
is treated with a fixing bath. Crusts as thin as five to ten percent of
the thickness of a ten to fifteen micron emulsion layer have been made.
During development, areas containing black irregular or oblong silver
particles are formed from activated silver-halide areas. The volume
concentration of activated silver halide at the emulsion surface
determines the volume concentration of oblong silver particles, which in
turn determines the optical density of the emulsion layer. Accordingly,
spots 84, 86, 88, and 90 contain few if any, silver particles since these
spot areas were mostly spots 74, 76, 78 and 80 of unexposed and
unactivated silver halide which were under dark spots 54, 56, 58 and 60 of
mask 52. Areas containing oblong silver particles should exhibit an
optical density as measured with red light of a photographic densitometer
of at least 0.5 and preferably greater than 1.0, while the unexposed areas
should have densities less than 0.2. Subsequent to development, fixing and
rinse steps remove the remaining silver halide from emulsion layer 66.
Exposed silver chloride emulsions, when developed, produce irregularly
shaped spheroidal silver particles which are highly absorptive, i.e.
black, and which respond to a laser recording beam by modification into
bright smooth spherical particles. However, exposed silver bromide
emulsions tend to produce filamentary silver particles when developed.
Filamentary silver, while black, does not respond to the recording laser
beam in the same way as irregular spheroid silver particles, and when
filamentary silver is present in the thin crust, laser recording
performance is greatly degraded. In order to produce irregular spheroidal
silver particles from a silver bromide emulsion, organic stabilizers or
antifoggants are included in the developing solution. These compounds
include, for example, organic thiols, such as
1-phenyl-1H-tetrazole-5-thiol, 1-phenyl-2-imidazolidine-thione, and
4,4,5-trimethyl-4H-pyrazole-3thiol. Previously, these compounds have been
used to control growth of reflective silver spheres in diffusion transfer
photography. In the present instance, the compounds attach themselves to
the unreacted silver bromide andinhibit the action of the chemical
developing agent. In doing so, the shape of the resulting silver grains is
that of irregular spheroids which form a crust with substantial covering
power, i.e. low transmissivity. As already noted, silver chloride
emulsions do not require the use of organic antifoggants to produce
irregular spheroid silver grains.
When an antihalation dye is not used, effects of halation in emulsion layer
66 during exposure to actinic radiation are minimized when the emulsion
layer 66 is very thin, i.e. less than 5 microns, and when metallic layer
68 beneath emulsion layer 66 is substantially less reflective at the
wavelengths of the actinic radiation. In FIG. 7, the reflectivities of
gold, copper, silver and aluminum at different wavelengths are seen. At
the read beam wavelength in the near infrared, i.e. a wavelength longer
than 0.8 microns, all of the metals have a reflectance of at least 80
percent and all but aluminum have a reflectance greater than 90 percent.
Thus, each metal has a high reflectivity to produce a high optical
contrast of reflective data spots against a dark background for reading.
Gold and copper are substantially less reflective at a wavelength of
actinic light in the range from 0.4 to 0.6 microns, i.e. for blue and
green light. For example, gold has a reflectance of approximately 35 to 40
percent for wavelengths less than 0.5 microns. Copper has a reflectance of
less than 60 percent for wavelengths shorter than 0.6 microns. These
reduced reflectances reduce the halation effects.
Silver and aluminum both have reflectances of greater than 80 percent for
wavelengths between 0.4 and 0.6 microns. Accordingly, silver and aluminum
are less suitable for media to be exposed to actinic radiation in this
wavelength range. In fact, aluminum has greater reflectance for
wavelengths in the 0.4 to 0.6 micron range than for wavelengths in the
near infrared range from 0.8 to 1.0 microns. To compensate for this,
aluminum metallic layers may be used with thinner photosensitive emulsion
layers to minimize the halation effect and can still be suitable for
emulsions two to three microns thick. Also, antihalation dyes may be used.
The present invention utilizes a very thin black silver crust within one of
the planar surfaces of a gelatin layer and a reflective under layer to
achieve good recording sensitivity, high contrast and resolution laser
recording and pre-recording of tracks and data and also permits laser
recording of track, and other formatting data. The card can also be used
as a read only memory card with prerecorded tracks and data and without
user recording of data.
A laser apparatus is illustrated in FIG. 8, which illustrates the side view
of the lengthwise dimension of the card of FIG. 1. The data medium 41 of
the card is usually received in a movable holder 39 which brings the strip
into the trajectory of a laser beam. A laser light source 43, preferably a
pulsed semiconductor laser of near infrared wavelength emits a beam 45
which passes through collimating and focusing optics 47. The beam is
sampled by a beam splitter 49 which transmits a portion of the beam
through a focusing lens 51 to a photodetector 53. The detector 53 confirms
laser writing and is not essential. The beam is then directed to a first
servo controlled mirror 55 which is mounted for rotation along axis 57 in
the direction indicated by arrows B. The purpose of the mirror 55 is to
find the lateral edges of the recording medium in a coarse mode of
operation and then in a fine mode of operation identify data paths which
exist predetermined distances from the edges.
From mirror 55, the beam is directed toward a mirror 61. This mirror is
mounted for rotation at pivot 63. The purpose of mirror 55 is for fine
control of motion of the beam along the length of the data strip. Coarse
control of the lengthwise portion of the data strip relative to the beam
is achieved by motion of the movable holder 39. The position of the holder
may be established by a linear motor adjusted by a closed loop position
servo system of the type used in magnetic disk drives. Reference position
information may be pre-recorded on the card so that position error signals
may be generated and used as feedback in motor control. After reading one
data path, the mirror 55 is slightly rotated or turned. The motor moves
holder 39 lengthwise so that the path can be read again, and s | | |
