U.S. patent application number 10/290068 was filed with the patent office on 2003-07-03 for novel reading inhibit agents.
This patent application is currently assigned to Aprilis, Inc.. Invention is credited to Kolb, Eric S., Waldman, David A., Wang, Chunming.
Application Number | 20030123380 10/290068 |
Document ID | / |
Family ID | 23300296 |
Filed Date | 2003-07-03 |
United States Patent
Application |
20030123380 |
Kind Code |
A1 |
Waldman, David A. ; et
al. |
July 3, 2003 |
Novel reading inhibit agents
Abstract
Disclosed is an optical disk, card or media which comprises: a)
a plurality of data structures that are readable by the
interrogating beam of light; and b)a composition on or in the
optical disk, card or media disposed so that when the optical disk,
card or media is used in the optical read-out system, the
interrogating beam of light passes through the composition before
or after contacting some or all of the data structures. The
composition comprises a polymeric matrix with an organometallic
complex dissolved therein or with metal, transition metal, metal
oxide or transition metal oxide nanoparticles uniformly dispersed
therein. The composition is substantially transparent to the
interrogating beam and/or is substantially colorless.
Alternatively, the composition comprises a solid polymeric matrix
with an olefinic compound dissolved or uniformly dispersed therein
wherein double bond in the olefinic compound undergoes oxidative
cleavage promoted by a transition metal catalyst and a thiophenol
or a catalytic amount of a thiyl radical and wherein the
composition is substantially transparent to the interrogating beam
and/or is substantially colorless.
Inventors: |
Waldman, David A.; (Concord,
MA) ; Kolb, Eric S.; (Acton, MA) ; Wang,
Chunming; (Tewksbury, MA) |
Correspondence
Address: |
HAMILTON, BROOK, SMITH & REYNOLDS, P.C.
530 VIRGINIA ROAD
P.O. BOX 9133
CONCORD
MA
01742-9133
US
|
Assignee: |
Aprilis, Inc.
Maynard
MA
|
Family ID: |
23300296 |
Appl. No.: |
10/290068 |
Filed: |
November 6, 2002 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
60332889 |
Nov 6, 2001 |
|
|
|
Current U.S.
Class: |
369/275.4 ;
369/285; 430/270.11; G9B/20.002; G9B/7.145; G9B/7.17; G9B/7.181;
G9B/7.186 |
Current CPC
Class: |
G11B 20/00586 20130101;
Y10T 428/21 20150115; G11B 20/00086 20130101; G11B 7/254 20130101;
G11B 7/251 20130101; Y10S 430/146 20130101; G11B 7/244 20130101;
G11B 7/257 20130101 |
Class at
Publication: |
369/275.4 ;
369/285; 430/270.11 |
International
Class: |
G11B 007/24 |
Claims
What is claimed is:
1. An optical disk, card or media for use in an optical read-out
system that comprises a light source operative to produce an
interrogating beam of light for reading data structures, wherein
the optical disk, card or media comprises: a. a plurality of data
structures that are readable by the interrogating beam of light; b.
a composition on or in the optical disk, card or media disposed so
that when the optical disk, card or media is used in the optical
read-out system, the interrogating beam of light passes through the
composition before or after contacting some or all of the data
structures, wherein the composition comprises a polymeric matrix
with an organometallic complex dissolved therein or with metal,
transition metal, metal oxide or transition metal oxide
nanoparticles uniformly dispersed therein and wherein the
composition is substantially transparent to the interrogating beam
and/or is substantially colorless.
2. The optical disk or card of claim 1 further comprising: a. a
metallic layer; and b. a substrate disposed in a confronting
relationship with the metallic layer.
3. The optical disk or card of claim 2 wherein the composition is a
film superimposed over at least some of the data structures.
4. The optical disk or card of claim 2 wherein the composition is
interposed between the metallic layer and the substrate.
5. The optical disk or card of claim 2 wherein the organometallic
complex or nanoparticles react when exposed to an ambient condition
to form a product which reduces the transparency of the composition
to the interrogating beam and/or increases the coloration of the
composition.
6. The optical disk or card of claim 2 wherein the organometallic
complex or nanoparticles react when exposed to oxygen, moisture,
light and/or heat to form a product which reduces the transparency
of the composition to the interrogating beam and/or increases the
coloration of the composition.
7. The optical disk or card claim 6 wherein the composition is a
solid solution of an organometallic complex dissolved in a
polymeric matrix.
8. The optical disk or card of claim 7 wherein the organometallic
complex is a cyclopentadienyl or CO complex of iron, chromium,
nickel, cobalt, titanium, tungsten, platinum or ruthenium.
9. The optical disk or card of claim 8 wherein the organometallic
complexes is Fe(CO).sub.5 complex, Co.sub.2(CO).sub.8 complex or
nickel cyclooctoadiene complex.
10. The optical disk or card of claim 6 wherein the composition is
a solid polymeric matrix with metal, transition metal, metal oxide
or transition metal oxide nanoparticles uniformly dispersed
therein.
11. The optical disk or card of claim 10 wherein the metal or
transition metal nanoparticles oxidize when exposed to air.
12. The optical disk or card of claim 11 wherein metal or
transition metal is Al, Si, Cr, Fe, Co, Ni, Cu, Zn, In, Sn, Ag, Au,
Pt, Pd, Mo or W.
13. The optical disk or card of claim 10 further comprising a
ligand which stabilizes the metal or transition metal
nanoparticles.
14. The optical disk or card of claim 13 wherein the metal or
transition metal is Au, Ag, Pt or Pd and the ligand is a monovalent
substituted or unsubstituted thio-alkyl, thio-cycloalkyl,
thio-arylalkyl, sulfide or disulfide ligand.
15. The optical disk or card of claim 13 wherein the metal or
transition metal is Fe, Al, Cu or Co and the ligand is an alkyl
carboxylic acid.
16. The optical disk or card of claim 6 wherein the polymeric
matrix is a thermoplastic polymer.
17. The optical disk or card of claim 6 wherein the polymeric
matrix is formed from a photopolymerizable or thermopolmerizable
monomer and/or oligomer comprising ethylenically unsaturated
groups, epoxide groups or combinations thereof.
18. An optical disk, card or media for use in an optical read-out
system that comprises a light source operative to produce an
interrogating beam of light for reading data structures,
comprising: a. a plurality of data structures that are readable by
the interrogating beam of light; and b. a composition on or in the
optical disk disposed so that when the optical disk, card or media
is used in the optical read-out system, the interrogating beam of
light passes through the composition before or after contacting
some or all the of the data structures, wherein the composition
comprises: i) a solid polymeric matrix with an olefinic compound
dissolved or uniformly dispersed therein; and ii) a transition
metal catalyst and a thiophenol or a catalytic amount of a thiyl
radical and wherein the composition is substantially transparent to
the interrogating beam and/or is substantially colorless.
19. The optical disk or card of claim 18 further comprising: a. a
metallic layer; and b. a substrate disposed in a confronting
relationship with the metallic layer.
20. A method for coating an internal or external surface of a
device with a layer that is substantially transparent to visible
light wherein the layer undergoes a reduction in said transparency
when exposed to an ambient condition, said method comprising the
steps of: a. dispensing onto the surface a film of a solution
comprising at least one monomer or at least one oligomer, wherein
the solution additionally comprised an organometallic complex,
metal, transition metal, metal oxide or transition metal oxide
nanoparticles dissolved therein or uniformly dispersed therein; and
b. polymerizing the monomer(s) or oligomer(s) to form a
polymer.
21. The method of claim 20 wherein the device is an optical disk or
card or a part used in the manufacture of an optical disk or
card.
22. The method of claim 21 wherein the device is a substrate,
metallized layer, information carrying layer or barrier layer used
in the manufacture of an optical disk or card.
23. The method of claim 21 wherein the organometallic complex or
nanoparticles react when exposed to an ambient condition to form a
product which reduces the transparency of the layer or increases
the coloration of the layer.
24. The method of claim 21 wherein the organometallic complex or
nanoparticles react when exposed to an ambient condition to form
light scattering centers.
25. The method of claim 22 wherein the organometallic complex or
nanoparticles react when exposed to oxygen, moisture, light and/or
heat to form a product which reduces the transparency of the
polymerized monomer or increases the coloration of the layer.
26. The method claim 25 wherein the monomer solution comprises an
organometallic complex dissolved therein.
27. The method of claim 26 wherein the organometallic complex is a
cyclopentadienyl or CO complex of iron, chromium, nickel, cobalt,
titanium, tungsten, platinum or ruthenium.
28. The method of claim 27 wherein the organometallic complex is
Fe(CO).sub.5 complex, Co.sub.2(CO).sub.8 complex or nickel
cyclooctadiene.
29. The method of claim 25 wherein the monomer solution comprises
metal, transition metal, metal oxide or transition metal oxide
nanoparticles uniformly dispersed or dissolved therein.
30. The method of claim 29 wherein the metal or transition metal
nanoparticles oxidize when exposed to air.
31. The method of claim 30 wherein metal or transition metal is Al,
Si, Cr, Fe, Co, Ni, Cu, Zn, In, Sn, Ag, Au, Pt, Pd, Mo or W.
32. The method of claim 29 wherein the monomer solution further
comprises a ligand which stabilizes the metal or transition metal
nanoparticles.
33. The method of claim 32 wherein the metal or transition metal is
Au, Ag, Pt or Pd and the ligand is a monovalent substituted or
unsubstituted thio-alkyl, thio-cycloalkyl, thio-arylalkyl, sulfide
or disulfide ligand.
34. The method of claim 32 wherein the metal or transition metal is
Fe, Al, Cu or Co and the ligand is an alkyl carboxylic acid.
35. The method of claim 25 wherein the monomer solution comprise
one or more monomers or oligoner(s) which form thermoplastic a
polymer when polymerized.
36. The method of claim 25 wherein the monomer or oligomer is
olefinic or epoxy monomer or oligomer that is photopolymerizable or
thermopolymermizable.
37. A method for coating an internal or external surface of a
device with a layer that is substantially transparent to visible
light wherein the layer undergoes a reduction in said transparency
when exposed to an ambient condition, said method comprising the
steps of: a. dispensing onto the surface a film of a solution
comprising: i) least one monomer or oligomer with an olefinic
compound dissolved or uniformly dispersed therein; and ii) a
transition metal catalyst and a thiophenol or a catalytic amount of
a thiyl radical; and b. polymerizing the monomer.
38. A method for coating an internal or external surface of a
device with a layer that is substantially transparent to visible
light wherein the layer undergoes a reduction in said transparency
when exposed to an ambient condition, said method comprising the
steps of: a. dispensing onto the surface a film of a solution of at
least one polymer, wherein the solution additionally comprises an
organometallic complex, metal, transition metal, metal oxide or
transition metal oxide nanoparticles dissolved therein or uniformly
dispersed therein; and b. removing the solvent from the solution to
form the coating.
39. The method of claim 38 wherein the device is an optical disk or
card or a part used in the manufacture of an optical disk or
card.
40. The method of claim 39 wherein the device is a substrate,
metallized layer, information carrying layer or barrier layer used
in the manufacture of an optical disk or card.
41. The method of claim 39 wherein the organometallic complex or
nanoparticles react when exposed to an ambient condition to form a
product which reduces the transparency of the layer or increases
the coloration of the layer.
42. The method of claim 39 wherein the organometallic complex or
nanoparticles react when exposed to an ambient condition to form
light scattering centers.
43. The method of claim 40 wherein the organometallic complex or
nanoparticles react when exposed to oxygen, moisture, light and/or
heat to form a product which reduces the transparency of the
polymerized monomer or increases the coloration of the layer.
44. The method claim 43 wherein the monomer solution comprises an
organometallic complex dissolved therein.
45. The method of claim 44 wherein the organometallic complex is a
cyclopentadienyl or CO complex of iron, chromium, nickel, cobalt,
titanium, tungsten, platinum or ruthenium.
46. The method of claim 45 wherein the organometallic complex is
Fe(CO).sub.5 complex, Co.sub.2(CO).sub.8 complex or nickel
cyclooctadiene.
47. The method of claim 43 wherein the monomer solution comprises
metal, transition metal, metal oxide or transition metal oxide
nanoparticles uniformly dispersed or dissolved therein.
48. The method of claim 47 wherein the metal or transition metal
nanoparticles oxidize when exposed to air.
49. The method of claim 48 wherein metal or transition metal is Al,
Si, Cr, Fe, Co, Ni, Cu, Zn, In, Sn, Ag, Au, Pt, Pd, Mo or W.
50. The method of claim 47 wherein the monomer solution further
comprises a ligand which stabilizes the metal or transition metal
nanoparticles.
51. The method of claim 50 wherein the metal or transition metal is
Au, Ag, Pt or Pd and the ligand is a monovalent substituted or
unsubstituted thio-alkyl, thio-cycloalkyl, thio-arylalkyl, sulfide
or disulfide ligand.
52. The method of claim 50 wherein the metal or transition metal is
Fe, Al, Cu or Co and the ligand is an alkyl carboxylic acid.
53. The method of claim 43 wherein the monomer solution comprise
one or more monomers or oligoner(s) which form thermoplastic a
polymer when polymerized.
54. The method of claim 43 wherein the monomer or oligomer is
olefinic or epoxy monomer or oligomer that is photopolymerizable or
thermopolymermizable.
55. A method for coating an internal or external surface of a
device with a layer that is substantially transparent to visible
light wherein the layer undergoes a reduction in said transparency
when exposed to an ambient condition, said method comprising the
steps of: c. dispensing onto the surface a film of a solution
comprising: i) at least one polymer, with an olefinic compound
dissolved or uniformly dispersed therein; and ii) a transition
metal catalyst and a thiophenol or a catalytic amount of a thiyl
radical; and d. removing the solvent from the solution to form the
coating.
56. A method of limiting access to data stored on an optical disk,
card, media, said optical disk, card or media being used in an
optical read-out system that comprises a light source operative to
produce an interrogating beam of light for reading data structures,
said method comprising the step of exposing the optical disk, card
or media to an ambient condition, wherein the optical disk, card or
media comprises: a. a plurality of data structures that are
readable by the interrogating beam of light; b. a composition on or
in the optical disk, card or media disposed so that when the
optical disk, card or media is used in the optical read-out system,
the interrogating beam of light passes through the composition
before or after contacting some or all of the data structures,
wherein the composition comprises a polymeric matrix with an
organometallic complex dissolved therein or with metal, transition
metal, metal oxide or transition metal oxide nanoparticles
uniformly dispersed therein and wherein the composition is
substantially transparent to the interrogating beam and/or is
substantially colorless.
57. The method of claim 56 wherein the ambient condition is
exposure to the interrogating beam of light.
58. A method of limiting access to data stored on an optical disk,
card, said optical disk, card or media being used in an optical
read-out system that comprises a light source operative to produce
an interrogating beam of light for reading data structures, said
method comprising the step of exposing the optical disk, card or
media to an ambient condition, wherein the optical disk, card or
media comprises: a. a plurality of data structures that are
readable by the interrogating beam of light; and b. a composition
on or in the optical disk disposed so that when the optical disk,
card or media is used in the optical read-out system, the
interrogating beam of light passes through the composition before
or after contacting some or all the of the data structures, wherein
the composition comprises: i) a solid polymeric matrix with an
olefinic compound dissolved or uniformly dispersed therein; and ii)
a transition metal catalyst and a thiophenol or a catalytic amount
of a thiyl radical and wherein the composition is substantially
transparent to the interrogating beam and/or is substantially
colorless.
59. The method of claim 58 wherein the ambient condition is
exposure to the interrogating beam of light.
Description
RELATED APPLICATIONS
[0001] This application claims the benefit of U.S. Provisional
Application Serial No. 60/332,889, filed Nov. 6, 2001, the entire
teachings of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION
[0002] This invention relates to a method of using materials that
are applied to a disk or card or the like, such as would be used
for storing information, such that upon subsequent exposure to an
ambient condition said applied material changes from a
substantially transparent state to one that is substantially more
opaque as a consequence of the creation of light scattering
centers, color change, and/or reflectivity change, thereby limiting
the ability to read information from said disk, card, or the like
after the desired information has been read from the disk for a
certain duration of time.
[0003] U.S. Pat. No. 5,815,484 describes a limited play optical
disk using photochromism, defined as a phenomenon whereby
irradiation of a material by light exhibiting desirable wavelengths
effects reversible or irreversible changes to the optical
absorbance of the material. In particular, irradiation of a coating
comprising a photochromic material by light alters the reactive
material in the coating so as to change the coating from an
optically transparent to an optically opaque state. More
specifically, the aforementioned prior art describes the
combination of light and oxygen as the stimulus that changes the
absorbance characteristics of a photochromic material in response
to an interrogating beam of light having a wavelength desirably of
about 650 nm. It further describes that when the stimulus is
exclusively air, such as from the ambient environment, then the
reactive material, which for example comprises a compound selected
from a group of dye molecules, changes its state as a result of
oxidation from an optically transparent to an optically opaque
state that absorbs light of desirable wavelengths used for reading
the information from the disk. The active material is described as
preferably superimposed over some or all of the plurality of data
structures in the optical disk, in the form of a coating on a least
a portion of the outer surface of the substrate. U.S. Pat. No.
5,815,484 further specifies that if the material were to be
interposed between the substrate and the metallic layer then it
would be inherently more difficult to manufacture the optical
disk.
[0004] Compounds I and II, of U.S. Pat. No. 5,815,484, specifically
react upon exposure to 650 nm light at an intensity consistent with
the light sources for current DVD players. Moreover, these
compounds are photoreactive in the presence of oxygen from ambient
air upon exposure to either incandescent or fluorescent light.
Accordingly, it is required that compounds I and II, as part of a
coating applied to a disk, be stored in inert environment, free of
oxygen, prior to exposure to the light from sources such as
semi-conductor lasers used for the DVD players. U.S. Pat. No.
5,815,484 also specifies that oxygen reactive materials, for
example, the dye compound methylene blue, can be used as the
reactive compound that in its reduced form exhibits a pale yellow
color, and which re-oxidizes to a dark blue color upon exposure to
oxygen in ambient air. This dye and other described dye materials
only require exposure to oxygen, and not to the combination of
oxygen and light, for the desired change in absorbance
characteristics. Accordingly, it is also necessary to store the
optical disk containing a coating comprising such dyes in an inert
environment free of oxygen prior to use in a CD or DVD player. This
requires special packaging to prevent or substantially limit
diffusion of oxygen, and perhaps also the use of oxygen adsorbing
compounds as part of the packaging. Moreover, once the special
packaging is removed and the disk is exposed to ambient conditions,
then the coating applied to the disk and which contains the
reactive materials must also have been protected against solvents
that could subsequently be used to remove or alter said reactive
materials, and also protected from use of mechanical methods, such
as, for example, polishing or grinding that could be used to remove
said coating. The use of such reactive compounds does not
contemplate the future use of semi-conductor lasers with shorter
wavelengths for more advanced optical disk technologies.
Specifically, the dye compounds described would not be appropriate
for DVD players incorporating the use of lasers emitting at say 405
nm.
[0005] U.S. Pat. No. 5,815,484 claims a method of limiting access
to data stored on an optical medium wherein said disk comprises an
area containing a plurality of readable data structures and which
is coincident with a reactive compound superimposed over at least a
portion of said data structures of said area. The reactive compound
is to be operated in an ambient environment containing oxygen and
the absorbance of light by the material, in response to a
combination of exposure to oxygen and to irradiation for some
duration of time by light having a wavelength within a selected
range, is altered causing a change in optical transmission from
said area. A requirement of exposure to both ambient environment
and irradiation for some duration of time is particularly
disadvantageous. The intensity of semiconductors lasers used in CD
and DVD players is not uniform from different manufacturers and
thus the duration of time for said irradiation will vary for
different players. Moreover, the selected range of wavelengths for
said irradiation would be difficult to implement, using the methods
contemplated, for a range as broad as between about 780 nm and 405
mn, as would be necessary to prevent defeatability of limited play
at shorter wavelengths and provide for useful backwards
compatibility.
[0006] U.S. Pat. No. 5,815,484 further claims an optical disk
adapted for use in an optical readout system such that the disk
comprises a film of a reactive compound which is operative to
change in response to a stimulus applied to the reactive compound.
The film is disposed as an overlayer on a substrate that is in a
confronting relationship with a reflecting metallic layer or
interposed between said metallic layer and the substrate. Said
stimulus is either visible light, infrared light, an ambient
environment containing light and oxygen, or air. When the claimed
optical disk is adapted specifically for the stimulus being only
air, then the reactive compound is operative after a duration of
time needed to oxidize and change the absorbance characteristics of
the material between a transparent and suitably opaque state that
absorbs light of the desired wavelength. An optical disk containing
a film comprising said reactive compound that is a chemically
reduced form of a dye is further claimed. It is also further
claimed that an improved optical disk contains a reactive compound
responsive to irradiation by the interrogating beam such that the
chemical characteristic of the compound is intentionally changed
between transparent and suitably opaque states by exposure to the
light, such that the altered reactive compound absorbs light of
desired wavelengths. The intensity of semiconductors lasers used in
CD and DVD players is not uniform from different manufacturers and
thus the required reduction in absorbance of the desired
wavelengths will vary for different players. Additionally, the
signal to noise requirements for detection of reflected light for
reading from DVD and CD media by photo-detectors in said players is
not uniform for players from different manufacturers. Moreover,
absorbance of the selected range of wavelengths would be difficult
to implement, using the methods contemplated, for a range as broad
as between about 780 nm and 405 nm, as would be necessary to
prevent defeatability of limited play at other wavelengths and
provide for useful backwards compatibility U.S. Pat. No. 5,815,484
additionally claims a method for limiting access to data stored on
an optical disk having a substrate, a metallic layer encoded with
information, and a reactive layer through which the radiation
passes prior to being reflected for reading, wherein the reactive
layer is exposed to an unspecified environmental stimulus that
changes the optical characteristic of said reactive layer from an
optically transparent state to an optically opaque state. The
claimed method suffers from a serious disadvantage that in practice
can substantially compromise and defeat the intended objective.
Although the patent specifies the importance of a method for
forming an opaque state in the reactive layer that absorbs light of
the desired wavelengths, opacity is not defined as being able to
withstand defeatability of the desired absorbance state that may
otherwise occur due to subsequent exposure of the disk to light
containing UV and/or visible wavelengths. Exposure of a disk
comprising the reactive material to light, such as readily
available and obtained from sunlight, mercury arc lamps, Xenon
flash lamps, etc. will generally photobleach the opacity of a
reactive layer comprising reactive compounds that are photoactive
materials such as defined in U.S. Pat. No. 5,815,484.
Photobleaching herein is defined as causing a substantial decrease
of said opacity exhibited by the reactive layer. Complete
photobleaching of the photoactive material in the reactive layer
causes said layer to exhibit a change from said opacity to a state
of relative transparency. Specifically, U.S. Pat. No. 5,815,484
contemplates and claims the use of quasi-stable photochromic
compounds, such as spiropyrans, and the use of organic dye
molecules such as methylene blue and related compounds. U.S. Pat.
No. 5,815,484 did not contemplate that the preferably formed state
of opacity in the reactive layer comprising said photoactive
compounds can be photobleached, especially when said compounds are
present in an environment that can alter the oxidized state, and
consequently the desired absorbance state at certain wavelengths
can be modified to cause the reactive layer to exhibit a relatively
undesired transparent state. Similarly, undesirable photobleaching
can effect a diminution in the level of absorbance exhibited at the
desired wavelengths, as well as a shift in the absorbance spectrum
such that absorbance at the desired wavelengths diminishes and is
no longer adequate to prevent reading of information from the
optical disk at the desired wavelengths emitted by the lasers used
for the players.
[0007] Organic dyes contemplated by U.S. Pat. No. 5,815,484 are
converted from a chemically reduced form or leuko state (non
absorbing at the interrogating wavelength) to the desired colored
state by oxidation via exposure to oxygen in ambient air to form a
suitably opaque state that absorbs light at the desired
wavelengths. While this process may be reversible, organic dyes
generally can be "photobleached" using UV irradiation, such as
readily available from sunlight, mercury arc lamps, Xenon flash
lamps, etc., and in certain cases loss of opacity can be effected
by simply exposing the reactive layer to elevated temperatures. The
photo-stability (stability to bleaching processes) and heat
stability of the dye is a fundamental problem with organic dyes not
contemplated by U.S. Pat. No. 5,815,484. Consequently, the
specified and claimed technology would require stabilizers and/or
additional protective layers to obviate the obvious defeatability
problems.
[0008] Another disadvantage with this technology is that it does
not anticipate the roadmap for the migration from long to
significantly shorter wavelengths for semi-conductor lasers used,
for example, by DVD players for reading of information from the
optical disk. The currently used lasers irradiate with wavelengths
at about 650 nm, while the roadmap devices currently being tested
for product introduction as soon as 2002 will have interrogating
wavelengths of only about 405 nm. Additionally, the technology does
not contemplate the possibility of an optical disc comprising the
specified light absorbing reactive layer as being read by more that
one type of player. For example, today DVD players commonly used on
personal computers, can read both CD and DVD type optical disk
media. This requires the use of more than one wavelength for the
interrogating laser employed to read information from the two types
of optical disks, and additionally the intensity of the lasers and
the signal to noise requirements of the photodetectors are not the
same. Accordingly, an optical disk that may be unplayable with one
type of device may have acceptable play-back characteristics for a
second type of device, and thus the desired goal of limited play
would not necessarily be achieved. Moreover, the intensities of
lasers differ for CD and DVD players made by different
manufacturers, as do the signal to noise requirements of the
optical pickups or detectors in these players. Consequently, the
degree of retained opacity necessary to prevent reading of
information on a disk is not the same for one type of manufactured
player versus another, and likely also varies as a function of time
of use of a particular player.
[0009] Other prior art, see for example U.S. Pat. No. 6,011,772 of
SpectraDisc Corp., describes a number of methods to limit optical
disc readability. Corrosion of the reflective Al layer (or other
metal used to reflect light of the laser from information-encoding
features so as to read the information on the disk) by the
incorporation or delivery of humidity (water) to form an
"electrolyte" at or near the surface of the reflective layer and
thus catalyze corrosion is such a method. It is preferred that
selective corrosion of the Al layer occur so as to cause sufficient
loss in reflectivity of the Al layer to prevent optical reading of
the encoded information on the disk. This invention, however does
not anticipate the current industrial practice incorporating a
protective barrier layer, typically SiOx which aggressively
prevents the corrosion of the metallic layer. The SiOx layer is
necessary to prevent premature corrosion of the metal layer during
manufacturing, especially in the case of Al reflective layers where
the outermost 100 angstroms of sputtered or vapor deposited layers
is known to be completely oxidized in microseconds even in
substantially purified environments, a problem that plagued the
industry in the past. U.S. Pat. No. 6,011,772 specifies that the
reflective layer of FIG. 16 is indeed protected by a barrier layer
to prevent such oxidation and physical damage, whereas U.S. Pat.
No. 5,815,484 specifies in FIGS. 3, 5, 6, and 7 the use of a
barrier layer located adjacent to the reflective layer.
[0010] U.S. Pat. No. 6,011,772 further specifies the use of a
barrier layer that would be releasably coupled to the disk and that
would prevent both machine-reading of the disk and activation of a
reading-inhibit agent (RIA). Consequently, the user of the optical
disk would be required to remove said barrier layer so as to allow
for reading of the information on the disk. Removal of this barrier
layer is specified to activate a reading-inhibit agent that will
subsequently alter the disk to inhibit reading of the disk after a
certain time of exposure of the disk to ambient environment that
contains oxygen and moisture and/or irradiation from the reading
laser beam of the optical drive. The requirement for diffusion of
oxygen and water vapor from the ambient environment through a
permeable layer, at a controlled rate, to the metal layer is
disadvantageous. The ambient environment is defined by where a
particular player is used and thus does not take into consideration
the considerable variability in humidity that generally exists in
different seasons and in different parts of a country or the world
in any season or even in the day versus the night. Accordingly, the
limited play time of such a disk could be highly variable
depending, for example, if the disk was even made for use in the
same state, such as for the case of Dallas versus Houston, Tex.
where the relative humidity can differ by at least 55%.
[0011] Additionally, U.S. Pat. No. 6,011,772 specifies that the
read inhibiting agents (hereinafter "RIA") can be activated by
machine-reading the disk such as by the optical radiation that is
incident on the disk during machine-reading or by rotation of the
disk during machine-reading. This approach suffers from some of the
same deficiencies as described above for U.S. Pat. No. 5,815,484.
In another embodiment of the barrier layer U.S. Pat. No. 6,011,772
specifies that said layer is formed instead as a closed package
that seals the entire optical disk from contact with the ambient
oxygen and moisture. This does not reduce the aforementioned
disadvantage of requiring activation by both ambient oxygen and
moisture.
[0012] In another embodiment U.S. Pat. No. 6,011,772 proposes to
inhibit reading of information on the disk by incorporation of
agents that scatter the reading beam. The scattering mechanism
disclosed employs an organic solvent and a polymer layer. The
polymer layer, when exposed to an organic solvent, depending on
concentration and exposure time, will experience a loss in
transparency. In this case the read-inhibiting agent is stated to
be the organic solvent working in concert with a polymer film.
While this method may work to prevent readability, and is readily
effected using common solvents and polymer materials such as
polycarbonate, the practicality of dispensing a volatile organic
solvent in an electronic device is limited. Solvent flammability,
toxicity, and volatility, solvent caused corrosive effects on
microelectronic circuitry found in the player, and solvent caused
deleterious structural changes to surfaces of the optical
components and/or their mounts in the CD and/or DVD player would
severely impact general usability and lifetime of the player. These
and other effects resulting from use of organic solvents for
purposes of scattering the reading laser beam would substantially
complicate the use and adoption of this embodiment of the specified
technology for the intended purpose of limiting the duration for
reading information from the said disk.
[0013] In another embodiment the inventor specifies the use of
optical radiation from a second optical source (i.e. high pressure
arc lamp, fluorescent lamp, incandescent lamp, laser) to activate
the read-inhibiting agent. The radiation source is coupled to the
interrogation beam such that the RIA is activated after the reading
beam has firstly read the data. While this method may provide a
method to activate the RIA, the coupling of such a secondary light
source is not currently employed in standard optical disc play
devices. The incorporation of such an activation mechanism would
limit the disc from a practicality standpoint unless the majority
of DVD and/or CD players incorporated the secondary light source.
Moreover, activation of the RIA and the subsequent increase in
absorbance of the wavelength used for the reading beam would
require different amounts of absorbance for different levels of
irradiance provided by reading beams in players from different
manufacturers. U.S. Pat. No. 6,011,772 also describes a second
source that would be sufficiently strong so as to obviate need for
a RIA, but in this case, for example, the light source could cause
ablation creating scattering centers that would limit access to
information on the disk immediately after the information is read.
A simpler approach is further described as an alternative wherein
the read/interrogation beam could itself be used to activate the
RIA. In this embodiment the RIA is contemplated to absorb some of
the intensity of the interrogation read beam and then the activated
RIA would attenuate the interrogating beam further and may inhibit
proper reading of the data during the read lifetime of the
disc.
SUMMARY OF THE INVENTION
[0014] This invention relates to a method of using materials that
are applied to a disk, card, media or the like, such as would be
used for storing information, such that upon subsequent exposure to
an ambient condition said applied material changes from a
substantially transparent state to one that is substantially more
opaque as a consequence of the creation of light scattering
centers, color change, and/or reflectivity change, thereby limiting
the ability to read information from said disk, card, media or the
like after the desired information has been read from the disk for
a certain duration of time without the typical disadvantages of
other methods such as susceptibility to photobleaching and/or lack
of opacity to other wavelengths of light contemplated to be used to
read the information.
[0015] The materials may be applied as a coating disposed as a
protected or non protected overlayer on a substrate that is in a
confronting relationship with a reflecting metallic layer, said
metallic layer being encoded with the information data structures
to be read or at least disposed as a layer on the structural
features comprising such information data structures, or the
material may be interposed between said metallic layer and the
substrate, or superimposed over at least a portion of a plurality
of readable data structures in the disk, card, media or the like,
such as would be used for storing information, or the material may
be applied in any other configuration including but not limited to
incorporation of the material into an adhesive bonding layer such
as used between the two sides of Digital Video Disks (DVD) or would
be contemplated for other optical disk or card technology
comprising two or more layers, or in other ways that would affect
the ability to interrogate the information data structures stored
in an optical disk, card, media or the like such that when the
material is activated it prevents reading of the disk, card, media
or the like after an initial time period during which the desired
information data structures can be read from the disk, card, media
or the like.
[0016] One embodiment of the present invention is an optical disk,
card or media for use in an optical read-out system that comprises
a light source operative to produce an interrogating beam of light
for reading data structures. The optical disk, card or media
comprises:
[0017] a. a plurality of data structures that are readable by the
interrogating beam of light; and
[0018] b. a composition on or in the optical disk, card or media
disposed so that when the optical disk, card or media is used in
the optical readout system, the interrogating beam of light passes
through the composition before or after contacting some or all of
the data structures. The composition comprises a polymeric matrix
with an organometallic complex dissolved therein or with metal,
transition metal, metal oxide or transition metal oxide
nanoparticles uniformly dispersed therein. The composition is
substantially transparent to the interrogating beam and/or is
substantially colorless. Alternatively, the composition comprises:
i) a solid polymeric matrix with an olefinic compound dissolved or
uniformly dispersed therein; and ii) a transition metal catalyst
and a thiophenol or a catalytic amount of a thiyl radical. The
composition is substantially transparent to the interrogating beam
and/or is substantially colorless.
[0019] Another embodiment of the present invention is a method of
limiting access to data stored on the optical disk, card or media
described above. The method comprises the step of exposing the
optical disk, card or media to an ambient condition.
[0020] Another embodiment of the present invention is a method for
coating an internal or external surface of a device with a layer
that is substantially transparent to visible light. The layer is
further characterized in that it undergoes a reduction in said
transparency when exposed to an ambient condition. The method
comprises the steps of:
[0021] a. dispensing onto the surface a film of a solution
comprising at least one monomer or at least one oligomer. The
solution additionally comprises an organometallic complex, metal,
transition metal, metal oxide or transition metal oxide
nanoparticles dissolved therein or uniformly dispersed therein.
Alternatively, the solution comprises: i) at least one monomer or
oligomer with an olefinic compound dissolved or uniformly dispersed
therein; and ii) a transition metal catalyst and a thiophenol or a
catalytic amount of a thiyl radical; and
[0022] b. polymerizing the monomer(s) or oligomer(s) to form a
polymer.
[0023] Another embodiment of the present invention is a method for
coating an internal or external surface of a device with a layer
that is substantially transparent to visible light. The layer
undergoes a reduction in said transparency when exposed to an
ambient condition. The method comprises the steps of:
[0024] a. dispensing onto the surface a film of a solution
comprising at least one polymer. The solution additionally
comprises an organometallic complex, metal, transition metal, metal
oxide or transition metal oxide nanoparticles dissolved therein or
uniformly dispersed therein. Alternatively, the solution comprises:
i) at least polymer with an olefinic compound dissolved or
uniformly dispersed therein; and ii) a transition metal catalyst
and a thiophenol or a catalytic amount of a thiyl radical; and
[0025] b. removing the solvent from the solution to form the
coating.
DETAILED DESCRIPTION OF THE INVENTION
[0026] This invention describes the method of using a solution of
organometallic complexes in a polymeric material, referred to as
metal-polymer composites, that, for example, may comprise as the
reading-inhibit agent (RIA) a colloidal dispersion of metal or
transition metal or metal-oxide or transition metal-oxide dispersed
uniformly as nano particulate in a polymeric matrix, so as to
exhibit a high degree of transparency to desirable wavelengths of
light for a limited time. The polymeric material and polymeric
matrix can be, but are not limited to, a solid which can, for
example, be characterized by a glass transition temperature that
could be higher than 200.degree. C. or lower to temperatures below
room temperature, or a gel. Both rigid or high modulus and soft or
low modulus solid polymers are contemplated.
[0027] Metal-polymer composites with a high degree of homogeneity
can, by way of example, be prepared by mixing a polymer solution
and the appropriate organometallic complex or precursor or by
solution growth techniques or direct implantation under influence
of an electric field or by dissolution in solutions of functional
polymers. Subsequent treatment, such as chemical or thermal, or use
of actinic radiation can transform the organometallic complex into
the corresponding metal or transition metal or metal oxide or
transition metal-oxide or some other desirable species. Under
appropriate conditions, this transformed species will exist as a
homogeneous dispersion of nanoparticles. "Nanoparticles" are
defined to be particles having a dimension no greater than about 50
nanometers in any one direction, preferably between about 5 to 30
nanometers in any one direction. Dry polymer coatings of such
nanoparticle dispersions will be optically transparent since the
particulate size of the nanoparticles will be less than about
{fraction (1/10)} the wavelength of visible light. Typically these
dispersions, and subsequent coatings maintain their homogeneity
under controlled environmental conditions, such conditions being
quite similar to those required for storage of proposed
limited-play disks in the aforementioned prior art. Methods to
control such environmental conditions are consistent with those
specified in the prior art.
[0028] This invention discloses, and in particular, describes the
use of colloidal dispersions in a polymeric matrix as the RIA to
limit the readability of an optical medium. The colloidal metal,
transition metal, metal oxide or the like, initially dispersed in a
polymer solution, functional polymer solution, or in a monomer or
oligomer containing medium that is polymerizable by use of light
and/or heat, exists in a polymer matrix layer that is substantially
colorless and substantially transparent to an interrogating beam of
optical irradiation for some desirable limited amount of time, and
where said desirable time is defined by what is necessary and/or
preferred for the intended use. Subsequently, the RIA can, for
example, after exposure to ambient conditions become
morphologically unstable forming aggregates that exhibit
substantially increased particulate size such that they act as
scattering sites to visible wavelengths and/or change color or
reflectivity or amount of transparency to said desirable
wavelengths. As used herein, "ambient conditions" means the
conditions under which the RIA is typically used. Oxygen and
moisture in the air, light used in optical read-out systems and
heat generated in optical read-out systems are examples of
conditions that are encompassed within the term "ambient
condition", as it is used herein.
[0029] In one embodiment the colloidal dispersion is a metal or
transition metal, which when exposed to oxygen in the air or from
some other source becomes oxidized to a metal oxide and, in turn
changes the physical nature of the dispersion which causes the
development of scattering centers throughout the polymer
matrix.
xM.sup.0[O].fwdarw.M.sub.xO.sub.y
[0030] where M includes but it not limited to elements such as Al,
Si, Cr, Fe, Co, Ni, Cu, Zn, In, Sn, Ag, Au, Pt, Pd, Mo, and W. The
preparation of the nano or colloidal dispersions of metals is known
in the art and is described for example, in T. W. Smith and D.
Wychick J. Phys. Chem. 1980, 84, 1621-1629, H. H. Huang etal.
Langmuir 1996, 12, 909-912 and H. Hirai, H. Wakabayashi and M.
Komiyama, Bull.Chem. Soc. Jpn., 1986 59, 367-372, the entire
teachings of which are incorporated herein by reference.
[0031] In another embodiment a colloidal dispersion of a noble
metal such as Au, Pt or Pd can be prepared as the RIA. Dispersions
of this type are stabilized by specific interactions between the
metal and ligands in the dispersion. These dispersions are stable
when protected from light or heat or air and in particular O.sub.2.
Exposure to various ambient conditions destabilizes the
ligand-metal interaction causing the noble metal to phase separate
or agglomerate, thereby forming aggregates that scatter visible
light or in extreme cases the film can become substantially
reflective to light. In some cases the metal may undergo a chemical
reaction forming a new species, such as a metal oxide, that will
change the color of the polymer layer and/or cause scattering by
precipitation or by a change in the refractive index of the metal
when it transforms to the metal oxide.
[0032] Alternately, the RIA could be a material that when dispersed
or dissolved in a polymeric matrix forms a layer with high
transparency to desirable wavelengths of light, and upon subsequent
exposure to ambient conditions the material undergoes a phase
change, chemical reaction or isomenzation of unsaturated chemical
bonds in its chemical structure to substantially reduce the
transparency of the film to said desirable wavelengths. The
chemical reaction could, by way of example, be catalyzed
carbon-carbon double bond cleavage due to olefin oxidation, such as
can be promoted by a transition metal catalyst and a thiophenol, or
catalytic amounts of a thiyl radical (see X. Baucherel, J. Uziel
and S. Juge in J. Org. Chem. 2001, 66, 4504-4510, the entire
teachings of which are incorporated herein by reference). Suitable
olefins include aryl olefins, aliphatic olefins, functionalized
olefins (e.g., functionalized with esters, ketones, nitrites,
carboxylic acids and the like); suitable transition metal catalysts
include MnCl, V(acac).sub.3, VCl.sub.3, Vanadium oxo
bis(1-phenyl-1,3-dibutanedionate and the like); and suitable
thiophenols include unsubstituted thiophenol and thiophenols
substituted with halogens, alkyl groups and the like. Other
suitable olefins, transition metal catalysts and thiophenols are
disclosed in Baucherel et al.
[0033] The RIA can be incorporated as a coating on all or part of a
surface (internal or external surface) of device for which a change
in transparency and/or coloration is desirable upon exposure to an
ambient condition. The RIA can also be incorporated as a complete
or partial coating on a part from which such a device is assembled.
Examples of such devices include an optical disc, card, media (such
as holographic recording medium) and the like. The RIA can be
applied between the information carrying layer comprising data
structures or the reflective layer encoded with said information
data structures, said reflective layer may be disposed as a layer
on the features comprising such information data structures, and
the topmost or bottom surface of the disk, card, media or the like
or the RIA may be in the topmost or bottom layer of the disk, card,
media or the like, or it may be incorporated as an adhesive bonding
layer such as used between the two sides of DVD optical disks, or
may be contemplated for use in multilayer optical disks, cards,
media or the like, comprising two or more information carrying
layers comprising data structures, or in other ways that would
effect the ability to interrogate and read the information data
structures stored in or on an optical disc, card, media or the
like. The RIA can be incorporated, for example, as a coating on all
or part of a holographic recording medium so that the imaging
beam(s) pass through the RIA before or after contacting some or all
of the data structures. Holographic recording mediums are disclosed
in U.S. Pat. No. 6,212,148, WO 01/90817 and WO 97/13183, the entire
teachings of which are incorporated herein by reference. A "data
structure" is a structure in an optical disk, card or media that
stores information. In a CD or DVD, the data structures are a
sequence of pits and lands; in a holographic recording medium, the
data structures are regions or holographic recording; and in a
phase change medium such as a writable CD or DVD, the data
structures are related to regions of phase change.
[0034] More specifically, organometallic complexes that are used
for the RIA of the solid solution can be prepared by dissolving
metal or transition-metal carbonyl compounds in polymers or in
materials comprising one or more polymerizable monomer(s) and/or
oligomer(s). Solutions formed from the metal or transition-metal
compounds and polymers can, for example, be cast into solid films
on a surface such as the substrate, the metallized layer, a barrier
layer, or other layers contemplated for optical disks, cards, media
or the like, whereas solutions comprising polymerizable monomers
and/or oligomers can be dispensed onto any of the aforementioned
surfaces or other layers contemplated for optical disks, cards,
media or the like or into a gap between two such surfaces, and the
monomers and/or oligomers can be subsequently polymerized to form a
solid film by use of actinic radiation or heat or combinations
thereof. Decomposition of the metal or transition-metal compounds
to form uniform metal oxide dispersions causes significant changes
to the particle size exhibited by these materials such that the
solid solution changes from a substantially transparent
non-absorbing state, for desirable wavelengths of light, to a state
that scatters light effectively over a broad range of desirable
visible wavelengths extending from violet or short blue to red or
even to near IR. The polymer or subsequently polymerized monomers
or oligomers can additionally serve as a catalyst, via nonbonded
dispersive Van der Waals interactions and electrostatic type
interactions, such as charge-charge, charge-dipole or
dipole-dipole, for the desired decomposition of the metal or
transition-metal carbonyl compounds (see for example T. W. Smith
and D. Wychick, J. Phys. Chem. 84, 1621 (1980)). Fe(CO).sub.5 is
one such example of an organometallic complex that, by way of
example, as a liquid can be dissolved in polymers and thusly
prepared as a homogeneous solid solution in polymer films
[0035] Films comprising, for example, Fe(CO).sub.5 can exhibit
acute sensitivity to UV radiation causing rapid formation of the
reactive intermediate Fe(CO).sub.4 which reacts with excess
Fe(CO).sub.5 to form Fe.sub.2(CO).sub.9. The latter compound is
substantially more susceptible to oxidation and subsequent
decomposition to iron oxide, Fe.sub.2O.sub.3, can occur in
relatively short time periods as a consequence of exposure to
ambient conditions comprising air. Films that are adequately
shielded from light and/or air or are adequately protected by a
shielding layer, however, can be kept for long periods in the
presence of air without exhibiting significant decomposition.
[0036] Another example of such an organometallic complex that, by
way of example, can be used to form solid solutions in a broad
spectrum of polymers is Co.sub.2(CO).sub.8 (see P. H. Hess and H.
Parker, Jr. Appl. Polym. Sci., 10, 1915 (1966)), and the resultant
oxidation products are CoO and Co.sub.2O.sub.3. One advantage of
using organometallic complex materials as the RIA is that they can
be readily prepared in solutions using standard organic solvents or
in solutions of polymers or functional polymers or using
polymerizable monomers and/or oligomers, and these solutions
exhibit substantially enhanced stability to decomposition and
subsequent oxidation as compared to solid solutions (see for
example R. Tannenbaum, C. L. Flenniken and E. P. Goldberg, XI
International Conference on Oganometallic Chemistry, 1983, p.77)
that would be used as film type layers in or on an optical disk,
card, or the like. This is beneficial from the standpoint of
preparing materials for coatings in a way that is consistent with
manufacturing processes. Moreover, activation energies for
decomposition of, for example, the Fe(CO).sub.5 complex can exceed
35 kcal/mole in a solid solution of polymethylmethacrylate and 45
kcal/mole in polycarbonate (see R. Tannenbaum, E. P. Goldberg, and
C. L. Flenniken, "Decomposition of Iron Carbonyls in Solid Polymer
Matrices: Preparation of Novel Metal-Polymer Composites" in
Metal-Containing Polymeric Systems, eds. J. E. Sheats, C. E.
Carraher, Jr., and C. U. Pittman, Jr., Plenum Press, New York,
1985, pp. 320-327), values that are consistent with many of years
of storage of a disk comprising said complex prior to intended use.
Activation of the Fe(CO).sub.5 or Co.sub.2(CO).sub.8 complex can be
accomplished by exposure to UV radiation (see for example G. O.
Schenck, E. Koerner van Gustorf and Mon-Jon Tun, Tetrahedron
Letters, 1059 (1962)). Protection against subsequent oxidation in
the presence of air can be provided, independently or in
combination, by use of a barrier layer or use of inert gas in
packaging of the optical disk, card, or the like or use of oxygen
scavengers commonly found in packaging of foods, or other such
methods independently or in combination so as to prevent or slow
down diffusion of oxygen to the layer containing the RIA material.
Exposure to UV radiation for purposes of activating the RIA
material for subsequent oxidation can be readily implemented as
part of the manufacturing process of the limited play optical
disks, cards, or the like, such as would be used for an inline or
continuous-batch photolytic process that initiates polymerization
reactions in solutions comprising the RIA and monomers and/or
oligomers.
[0037] Polymers that are suitable for use in the disclosed
compositions and methods are substantially optically transparent
and substantially colorless. "Substantially optically transparent"
and "substantially colorless" means that when the polymer is
incorporated into or onto an optical disk, card or media, the
polymer does not interfere with the ability of the interrogating
beam of light used in the optical read-out system being used to
read the optical disk, card or media. Preferred polymers are
thermoplastic polymers and/or are formed from photopolymerizable or
thermopolmerizable monomer(s) and/or oligomer(s) comprising, but
not limited to, ethylenically unsaturated groups, epoxide groups or
combinations thereof Examples of suitable polymers include, but are
not limited to polystyrenes, polyacrylates, polyacrylonitriles,
polyesters, polycarbonates, polysulfones, polyalkylene oxides,
polypyrrolidones, polyamides, polyurethanes, polythiazoles,
poysiloxanes, polyphthalates, or copolymers thereof. Another
example includes polymers formed from hydrosilylation reactions
with, for example, vinylfunctionalized groupings and
hydrofunctionalized siloxanes. Typically, polymers suitable for use
in the disclosed invention have a threshold molecular weight
greater than 1000 amu.
[0038] Advantageously, the method contemplated in this invention
does not require any significant or difficult changes to the
existing manufacturing methodology used, for example, to prepare
optical discs for CD and/or DVD players. Additionally, the method
does not require special modification to the existing read device
technology. Moreover, this methodology does not require the
incorporation of hazardous volatile components to activate the RIA,
nor does it incorporate or create chemical species that would
interact unfavorably with components of the read device (i.e.
optical head) or of the optical drive itself. Additionally, and
perhaps most importantly, this invention provides a method to limit
the play time of an optical disc or card in a optical drive, such
as DVD or CD player, in a manner which can not be defeated by
photo-bleaching of the RIA, or by changing the wavelength of the
interrogating beam.
EXAMPLE
[0039] (1) A typical formulation comprising the RIA contemplated by
this invention is a formulation that preferably can be coated or
delivered to a surface or between surfaces by normal means, such as
spin coating, dip coating or the like, and is deposited on
recording media as a coating or as an interstitial adhesive layer
in a multilayer disc, card, or the like. The delivered formulation
preferably can be cured or crosslinked by normal techniques, such
as use of actinic radiation or heat, or alternatively it may be
cast from a solution into a polymer film without requiring a cure.
The cured, crosslinked or cast film or interstitial layer is
positioned intermediate between the stored information data and/or
file directory structures and the detector used to read said stored
information data and/or file directory structures. In such an
arrangement the interrogating beam used to read the media must
traverse said coating or layer at least once. The formulation, by
way of example, comprises an organometallic complex, a
polymerizable component or components, optionally a binder polymer
or oligomer, optionally a crosslinkable functional polymer or
oligomer, and polymerization initiation system. Alternatively, the
formulation comprises an organometallic complex and a polymer or
functional polymer or copolymer, or combinations thereof. The
organometallic complex can be any number of materials that degrade
in the presence of oxygen such as cyclopentadienyl complexes of
chromium, nickel, cobalt, titanium, tungsten or platinum or
ruthenium or others described in the above specification of the
invention such as an Fe(CO).sub.5 complex or Co.sub.2(CO).sub.8
complex. Another desirable feature of these organometallic
complexes would be the apparent auto-catalytic behavior these
materials exhibit upon decomposition. This would allow for good
control of the kinetics of decomposition and offer a superior
product over other candidates. (2) A typical formulation comprising
the RIA contemplated by this invention is a formulation that
preferably can be coated or delivered to a surface or between
surfaces by normal means, such as spin coating, dip coating or the
like, and is deposited on recording media as a coating or as an
interstitial adhesive layer in a multilayer disc, card, or the
like. The delivered formulation preferably can be cured or
crosslinked by normal techniques, such as use of actinic radiation
or heat, or alternatively it may be cast from a solution forming a
polymer film without requiring a cure. The cured, crosslinked or
cast film or interstitial layer is positioned intermediate between
the stored information data and/or file directory structures and
the detector used to read said stored information data and/or file
directory structures. In such an arrangement the interrogating beam
used to read the media must traverse said coating or layer at least
once. The formulation, by way of example, comprises a colloidal
suspension of a metal such as platinum, palladium, gold, or silver,
a polymerizable component or components, optionally a binder
polymer or oligomer, optionally a crosslinkable functional polymer
or oligomer, and polymerization initiation system, such that the
ligand-colloidal particle interaction or other electrostatic or
dispersive interaction stabilizing the colloid can be destabilized
in the presence of oxygen leading to agglomeration and/or phase
separation thereby forming particulates or aggregates that scatter
light. In such an example a surfactant or surfactant-like grouping
is, by way of example, independently, a monovalent substituted or
unsubstituted thio-alkyl, thio-cycloalkyl, thio-arylalkyl, sulfide,
or disulfide ligand that is used to stabilize a colloidal
suspension of a noble metal such as gold. It is well understood
that specific interactions between the alkanethiol, sulfide, and
disulfide ligand and the nanoparticle lead to stable colloidal
suspensions. It has also been observed that the interaction between
the alkanethiol, sulfide or disulfide ligand and the nanoparticle
are susceptible to air oxidation, destabilizing the ligand-metal
interaction leading to agglomeration or aggregation of the
nano-particles. Such aggregation substantially increases the size
of the particles and consequently visible light will be scattered
at locations of these particles in the suspension. Similar
behaviors are observed for alkyl carboxylic acid stabilized
colloidal suspensions of, for example, Fe, Al, Cu and Co.
EXEMPLIFICATION
Example 1
[0040] A transparent coating of a precursor to a read inhibiting
agent was prepared in the following manner. In a glove box or other
such inert, oxygen free environment, a vial was charged with 2.0
grams of an optical adhesive, OP21 from Dymax Corporation and 0.4
grams of Iron pentacarbonyl. Following mechanical stirring a
homogenous formulation was obtained. Two cells for testing the RIA
were prepared by sandwiching the formulation between two glass
slides, a base and a cover slip. The formulation was left to cure
in ambient light, .about.30 min. Next, one of the two cells was
removed from the glove box and the cells cover slip was carefully
removed. The pale yellow film was left exposed to ambient
conditions. After 5 hours the film had become dark brown in color.
The control sample in the glove box remained transparent pale
yellow.
Example 2
[0041] A transparent coating of a precursor to a read inhibiting
agent was prepared in the following manner. In a glove box or other
such inert, oxygen free environment, a vial was charged with 10
grams of a 50 wt % solution of Polystyrene (Aldrich product
33,165-1) in toluene previously degassed with N.sub.2. Next a
solution of Ni(COD)2 in toluene, 250 mg of Ni(COD)2 in 5 mL of
toluene was added to the polymer solution. After thorough mixing
the yellow orange solution was applied, via spin coating, to glass
substrate. After drying the pale orange film was exposed to ambient
conditions. After 1 hour the film developed haze which became quite
pronounced after .about.5 hours of exposure to ambient
conditions.
Example 3
[0042] A transparent coating of a precursor to a read inhibiting
agent was prepared in the following manner. In a glove box or other
such inert, oxygen free environment, a vial was charged with 3.0
grams of Dow Corning 93-500 Base, 0.30 grams of Dow Corning 93-500
curing agent and 3.3 mL of Toluene. To the polymer solution was
added 0.150 grams of Ni(COD).sub.2 dissolved in 3 mL of toluene.
After thorough mixing the yellow orange solution was applied, via
dip coating, to glass substrate. After drying the pale orange film
was exposed to ambient conditions. After 1 hour the film developed
haze which became quite pronounced after .about.3 hours of exposure
to ambient conditions.
[0043] The resulting reduction in transparency was evaluated using
illumination from a frequency doubled diode pumpled solid state
laser emitting at 532 nm. The spot dimensions corresponding to the
area of illumination was a square of 3 mm by 3 mm. The transmitted
intensity declined by a factor of between 4 and 17.5 depending upon
the thickness of the coated film. The decline in transparency
occurred resulted from the light being diffused into a larger area
as a consequence of the haze that was formed in the film.
[0044] While this invention has been particularly shown and
described with references to preferred embodiments thereof, it will
be understood by those skilled in the art that various changes in
form and details may be made therein without departing from the
scope of the invention encompassed by the appended claims.
* * * * *