Claims
- 1. In a process comprising locating adjacent support means areally extended along an axial plane a predetermined, ordered array of lateral wall means capable of defining microareas on the support means,
- positioning a first composition in one set of microareas on the support means,
- positioning a second composition on the support means in another, laterally displaced set of microareas which form an interlaid pattern with the one set of microareas,
- the improvement comprising
- establishing an electrostatic charge on a photoconductive portion of the support means defining the microareas,
- directing radiation toward the array at an acute angle with respect to the axial plane of the support means, the lateral wall means interrupting a portion of the radiation to create a first, shadowed set of microareas on the support means while permitting impingement of an uninterrupted portion of the radiation on a second, unshadowed, interlaid set of microareas of the support means, thereby removing the electrostatic charge in the second, unshadowed set of microareas by impingement of the uninterrupted portion of the radiation while retaining the electrostatic charge on the support means in the first, shadowed set of microareas, and
- selectively positioning an electrographic composition comprised of the first composition as a function of shadowing and the resulting electrostatic charge pattern in one set of the microareas.
- 2. The improved process according to claim 1, wherein the lateral wall means are located to present an array of substantially parallel lateral walls.
- 3. The improved process according to claim 2, wherein the parallel lateral walls are located on the support means to form microgrooves.
- 4. The improved process according to claim 3, wherein the parallel lateral walls are formed to present serpentine microgrooves.
- 5. The improved process according to claim 3, wherein the parallel lateral walls are located to form at least two interlaid sets of microgrooves.
- 6. The improved process according to claim 5, wherein the parallel lateral walls are spaced to form one set of microgrooves which differ in width from microgrooves of remaining sets.
- 7. The improved process according to claim 5, wherein the parallel lateral walls and the support means are formed to provide one set of microgrooves which differ in depth from remaining sets of microgrooves.
- 8. The improved process according to claim 1, wherein the lateral wall means are located on the support means to form microcells.
- 9. The improved process according to claim 8, wherein the microcells are formed to include at least one microarea from each set of microareas.
- 10. The improved process according to claim 8, wherein the lateral wall means are located on the support means to form at least two different sets of microcells.
- 11. The improved process according to claim 10, wherein the lateral wall means are located on the support means to form one set of microcells which are elongated, as compared to microcells of a second set, in a direction parallel to the axial plane of the support means.
- 12. The improved process according to claim 11, wherein the lateral wall means are located on the support means to form a second set of microcells which are elongated as compared to the microcells of the one set in a second direction parallel to the axial plane of the support means.
- 13. The improved process according to claim 11, wherein the two sets of microcells are related so that the second, unshadowed set of microareas are located entirely in the elongated set of the microcells.
- 14. The improved process according to claim 13, wherein means are positioned in the elongated set of microcells to enlarge the microareas of the second set so that the microareas of the first set are entirely excluded from the elongated set of microcells.
- 15. The improved process according to claim 1, wherein the microareas are less than 200 microns in size.
- 16. The improved process according to claim 15, wherein the microareas are in the range of from 4 to 100 microns in size.
- 17. The improved process according to claim 1, wherein the support means adjacent the microareas is formed of a substantially transparent material.
- 18. The improved process according to claim 17, wherein the lateral wall means are dyed to enhance their capability of interrupting radiation.
- 19. In a process of producing an element useful in multicolor photography comprising
- forming support means areally extended along an axial plane comprised of lateral wall portions and photoconductive bottom wall portions cooperating to form an array of microcells and
- sequentially positioning first, second, and third imaging compositions in first, second, and third interlaid sets of the microcells, respectively, the first, second, and third imaging compositions being chosen from among compositions which are responsive to or useful for absorbing light each in a different portion of the visible spectrum,
- the improvement comprising
- in forming the microcells, differentiating in at least one of depth, lateral extent along the axial plane, and orientation the microcells of the first set from the microcells of the remaining sets,
- establishing an electrostatic charge on the photoconductuve bottom wall portions forming the microcells,
- directing radiation toward the support means at an acute angle with respect to the axial plane, a portion of the radiation impinging on the bottom walls of the first set of the microcells while a remaining portion of the radiation is interrupted by the lateral walls to entirely shadow the bottom walls of the second and third sets of microcells, thereby removing the electrostatic charge from at least a portion of each of the photoconductive bottom wall portions of the first set of microcells while retaining the electrostatic charge on the photoconductive bottom wall portions of the second and third sets of microcells, and
- selectively positioning an electrographic composition comprised of the first imaging composition on the exposed bottom walls of the support in the first set of microcells.
- 20. The improved process according to claim 19, wherein the first set of microcells are formed to be diamond-shaped with their major axes aligned in a single direction.
- 21. The improved process according to claim 19, wherein the first set of microcells are formed to be rectangular with their major axes aligned in a single direction.
- 22. The improved process according to claim 19, wherein the first set of microcells are formed to be of lesser depth than the remaining sets of microcells.
- 23. The improved process according to claim 19, wherein, after initially directing radiation toward the support means at an acute angle with respect to the axial plane and before positioning the first imaging composition, the relationship of the support means to the initial direction of radiation is reversed 180.degree. in the axial plane and the step of directing radiation toward the support means at an acute angle with respect to the axial plane is repeated to selectively expose portions of the bottom walls of the first set of microcells which were shadowed during the first exposure.
- 24. In a process of producing an element useful in multicolor photography comprising
- forming support means areally extended along an axial plane comprised of lateral wall portions and photoconductive bottom wall portions cooperating to form an array of microcells and
- sequentially positioning first, second, and third imaging compositions in first, second, and third interlaid sets of microcells, respectively, the first, second, and third imaging compositions being chosen from among compositions each responsive to or useful in absorbing light in a different portion of the visible spectrum,
- the improvement comrising
- in forming the microcells, differentiating the microcells of each set from the microcells of the remaining sets in at least one of depth, lateral extent along the axial plane, and orientation,
- establishing an electrostatic charge on the photoconductive bottom wall portions forming the microcells,
- directing radiation toward the support means at an acute angle with respect to the axial plane to impinge a portion of the readiation on the bottom walls of the first set of the microcells while a remaining portion of the radiation is interrupted by the lateral walls to entirely shaodow the bottom walls of the second and third sets of microcells, thereby removing the electrostatic charge from at least a portion of each of the bottom wall portions of the first set of microcells while retaining the electrostatic charge on the photoconductive bottom wall portions of the second and third sets of microcells,
- selectively positioning a first electrographic composition comprised of the first imaging composition on the exposed bottom walls of the support in the first set of microcells,
- establishing an electrostatic charge on the photoconductive bottom wall portions of the second and third sets of microcells,
- directing radiation toward the support means at an acute angle with respect to the axial plane to impinge a portion of the radiation on the bottom walls of the second set of microcells while a remaining portion of the radiation is interrupted by the lateral walls to entirely shadow the bottom walls of the third set of microcells, thereby removing the electrostatic charge from at least a portion of each of the bottom wall portions of the second set of microcells while retaining the electrostatic charge on the photoconductive bottom wall portions of the third set of microcells, and
- selectively positioning a second electrographic composition comprised of the second imaging composition on the exposed bottom walls of the support in the second set of microcells.
- 25. The improved process according to claim 24, wherein radiation is subsequently directed toward the support means substantially perpendicularly to the axial plane to expose the bottom walls of the third set of microcells and selectively positioning the third imaging composition on the exposed bottom walls of the support in the third set of microcells.
- 26. The improved process according to claim 19, 20, 21, 22, 23, 24, or 25, wherein the first, second, and third compositions are each comprised of radiation-sensitive means responsive to a different portion of the spectrum.
- 27. The improved process according to claim 26, wherein the radiation-sensitive means is silver halide.
- 28. The improved process according to claim 19, 20, 21, 22, 23, 24, or 25, wherein the first, second, and third compositions are each comprised of a subtractive primary dye or dye precursor.
- 29. The improved process according to claim 28, wherein the first, second, and third compositions are each comprised of a different subtractive primary dye or dye precursor capable of shifting between a mobile and an immobile form as a function of silver halide development.
- 30. The improved process according to claim 19, 20, 21, 22, 23, 24, or 25, wherein the first, second, and third compositions are each comprised of a different additive primary colorant means.
- 31. A process comprising
- forming support means areally extended along an axial plane comprised of lateral wall portions and photoconductive bottom wall portions forming an interlaid pattern of at least two sets of microcells, the microcells of at least first and second sets each being relatively extended along a major axis parallel to the axial plane, the major axes of microcells of the same set being substantially aligned, and the major axes of microcells of the first and second sets being relatively oriented to intersect, whereby the microcells of at least the first and second sets can be uniquely addressed by radiation directed toward the support means at an acute angle with respect to the axial plane and substantially aligned with their major axes,
- establishing an electrostatic charge on photoconductive surfaces of the support means,
- uniquely addressing the bottom walls of the first set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane, thereby removing the electrostatic charge from at least a portion of the each of the bottom wall portions of the first set of microcells while retaining the electrostatic charge on the photoconductive bottom wall portions of the remaining microcells,
- selectively positioning a first electrographic composition comprised of a first radiation-sensitive material, colorant, or colorant precursor in the first set of microcells as a function of selective exposure of the bottom walls thereof,
- again establishing an electrostatic charge on photoconductive surfaces of the support means,
- uniquely addressing the bottom walls of the second set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane, thereby removing the electrostatic charge from at least a portion of each of the bottom wall portions of the second set of microcells while retaining the electrostatic charge on the bottom wall photoconductive surfaces of remaining of the microcells, and
- selectively positioning a second electrographic composition comprised of a second radiation-sensitive material, colorant, or colorant precursor in the second set of microcells as a function of selective exposure of the bototom walls thereof.
- 32. A process comprising
- forming support means areally extended along an axial plane comprised of bottom wall portions and lateral wall portions forming an interlaid pattern of at least two sets of microcells, the microcells of at least first and second sets each being relatively extended along a major axis parallel to the axial plane, the major axes of microcells of the same set being substantially aligned, and the major axes of microcells of the first and second sets being relatively oriented to intersect, whereby the microcells of at least the first and second sets can be uniquely addressed by radiation directed toward the support means at an acute angle with respect to the axial plane and substantially aligned with their major axes,
- positioning a radiation-sensitive means on the bottom walls of the microcells,
- uniquely addressing the bottom walls of the first set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane,
- selectively immobilizing a first dye on the bottom walls of the first set of microcells as a function of exposure to radiation,
- uniquely addressing the bottom walls of the second set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane, and
- selectively immobilizing a second dye on the bottom walls of the second set of microcells as a function of exposure to radiation.
- 33. A process according to claim 32 in which silver halide is positioned as the radiation-sensitive means on the bottom walls of the microcells.
- 34. A process according to claim 33 in which the first and second dyes are formed by development of exposed silver halide to form oxidized developing agent and reacting the oxidized developing agent with a mobile dye-forming coupler to form an immobile dye.
- 35. A process comprising
- forming support means areally extended along an axial plane comprised of bottom wall portions and lateral wall portions forming an interlaid pattern of at least two sets of microcells, the microcells of at least first and second sets being relatively extended along a major axis parallel to the axial plane, the major axes of microcells of the same set being substantially aligned, and the major axes of microcells of the first and second sets being relatively oriented to intersect, whereby the microcells of at least the first and second sets can be uniquely addressed by radiation directed toward the support means at an acute angle with respect to the axial plane and substantially aligned with their major axes,
- positioning a dye immobilizing layer on the bottom walls of the microcells,
- overcoating the dye immobilizing layer with a positive-working photoresist,
- uniquely addressing the bottom walls of the first set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane,
- removing the photoresist that is exposed to radiation, so that the photoresist is at least partially removed from the bottom walls of the microcells of the first set, but remains on the bottom walls of the remaining microcells,
- spreading a first mobile dye over the support means so that it is immobilized by the dye immobilizing layer on the bottom walls of the first set of microcells, but prevented from contacting the immobilizing layer on the bottom walls of the remaining microcells by the overcoated photoresist,
- removing the first mobile dye from the bottom walls of the remaining microcells,
- again overcoating the dye immobilizing layer with a positive-working photoresist,
- uniquely addressing the bottom walls of the second set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane,
- removing the photoresist that is exposed to radiation, so that the photoresist is at least partially removed from the bottom walls of the microcells of the second set, but remains on the bottom walls of the remaining microcells,
- spreading a second mobile dye over the support means so that it is immobilized by the dye immobilizing layer on the bottom walls of the second set of microcells, but prevented from contacting the immobilizing layer on the bottom walls of the remaining microcells by the overcoated photoresist, and
- removing the second mobile dye from the bottom walls of the remaining microcells.
- 36. A process comprising
- forming support means areally extended along an axial plane comprised of bottom wall portions and lateral wall portions forming an interlaid pattern of at least two sets of microcells, the microcells of at least first and second sets being extended along a major axis parallel to the axial plane as compared to their width, the major axes of microcells of the same set being substantially aligned, and the major axes of microcells of the first and second sets being relatively oriented to intersect, whereby the microcells of at least the first and second sets can be uniquely addressed by radiation directed toward the support means at an acute angle with respect to the axial plane and substantially aligned with their major axes,
- positioning a first mobile dye on the bottom walls of the microcells,
- overcoating the mobile dye with a first negative-working photoresist layer,
- uniquely addressing the bottom walls of the first set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane,
- removing the first photoresist layer that is unexposed to radiation, so that the first photoresist layer remains only on the bottom walls of the first set of microcells, but is entirely removed from the bottom walls of the microcells, of the second set,
- removing the first mobile dye from areas where the first photoresist layer is removed,
- locating a second mobile dye on the support so that it is positioned in the bottom walls of the microcells
- overcoating the second mobile dye with a second, negative-working photoresist layer,
- uniquely addressing the bottom walls of the second set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane,
- removing the second photoresist layer that is unexposed to radiation, so that the second photoresist layer remains only on the bottom walls of the second set of microcells, but is entirely removed from the bottom walls of the first set of microcells, and
- removing the second mobile dye from areas where the second photoresist layer is removed.
- 37. A process comprising
- forming support means areally extended along an axial plane comprised of lateral wall portions and photoconductive bottom wall portions forming an interlaid pattern of at least two sets of microcells, the microcells of at least first and second sets each being extended as compared to their width along a major axis parallel to the axial plane as compared to their width, the major axes of the microcells of the same set being substantially aligned, and the major axes of microcells of the first and second sets being relatively oriented to intersect, whereby the microcells of at least the first and second sets can be uniquely addressed by radiation directed toward the support means at an acute angle with respect to the axial plane and substantially aligned with their major axes,
- establishing an electrostatic charge on photoconductive surfaces of the support means,
- uniquely addressing the bottom wall portions of the first set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane, thereby selectively removing electrostatic charge from the exposed bottom wall portions of the first set of microcells while retaining the electrostatic charge on the bottom wall portions of the second set of microcells,
- selectively depositing a first electrographic imaging composition in the first set of microcells,
- uniquely addressing the bottom wall portions of the second set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane, thereby selectively removing electrostatic charge from the exposed, second set of microcells, and
- selectively depositing a second electrographic imaging composition in the second set of microcells.
- 38. A process according to claim 37 in which radiation penetrable conductive layer segments are positioned on the bottom walls of the microcells, so that the electrostatic charge is reduced over the entire bottom wall surface of each microcell at least partially addressed by radiation.
- 39. A process according to claim 38 in which the support means initially presents a substantially planar photoconductive surface and a planar conductive layer coated on the planar surface, the microcells being formed in the support by embossing the planar surface, and the planar conductive layer being separated by embossing into discrete laterally spaced segments laying on the bottom walls of the microcells.
- 40. In a process comprising
- locating adjacent support means areally extended along an axial plane a predetermined, ordered array of lateral wall means capable of defining microareas on the support means,
- positioning a first composition in one set of microareas on the support means,
- positioning a second composition on the support means in another, laterally displaced set of microareas which form an interlaid pattern with the one set of microareas,
- the improvement comprising
- positioning a radiation-sensitive material on the support means,
- directing radiation toward the array at an acute angle with respect to the axial plane of the support means, the lateral wall means interrupting a portion of the radiation to create a first, shadowed set of microareas on the support means while permitting impingement of an uninterrupted portion of the radiation of a second, unshadowed, interlaid set of microareas of the support means, so that the radiation-sensitive material is selectively exposed in the second set of microareas by impingement of the radiation, but is not exposed to radiation in the first, shadowed set of microareas,
- visibly differentiating the first and second sets of microareas as a function of exposure exposure or shadowing of the radiation-sensitive material, and
- selectively positioning the first composition as a function of exposure or shadowing in one set of the microareas.
- 41. The improved process according to claim 40, wherein the lateral wall means are located to present an array of substantially parallel lateral walls.
- 42. The improved process according to claim 41, wherein the parallel lateral walls are located on the support means to form microgrooves.
- 43. The improved process according to claim 42, wherein the parallel lateral walls are formed to present serpentine microgrooves.
- 44. The improved process according to claim 42, wherein the parallel lateral walls are located to form at least two interlaid sets of microgrooves.
- 45. The improved process according to claim 44, wherein the parallel lateral walls are spaced to form one set of microgrooves which differ in width from microgrooves of remaining sets.
- 46. The improved process according to claim 44, wherein the parallel lateral walls and the support means are formed to provide one set of microgrooves which differ in depth from remaining sets of microgrooves.
- 47. The improved process according to claim 40, wherein the lateral wall means are located on the support means to form microcells.
- 48. The improved process according to claim 47, wherein the microcells are formed to include at least one microarea from each set of microareas.
- 49. The improved process according to claim 47, wherein the lateral wall means are located on the support means to form at least two different sets of microcells.
- 50. The improved process according to claim 49, wherein the lateral wall means are located on the support means to form one set of microcells which are elongated, as compared to microcells of a second set, in a direction parallel to the axial plane of the support means.
- 51. The improved process according to claim 50, wherein the lateral wall means are located on the support means to form a second set of microcells which are elongated as compared to the microcells of the one set of in a second direction parallel to the axial plane of the support means.
- 52. The improved process according to claim 50, wherein the two sets of microcells are related so that the second, unshadowed set of microareas are located entirely in the elongated set of the microcells.
- 53. The improved process according to claim 52, wherein means are positioned in the elongated set of microcells to enlarge the microareas of the second set so that the microareas of the first set are entirely excluded from the elongated set of microcells.
- 54. The improved process according to claim 40, wherein the microareas are less than 200 microns in size.
- 55. The improved process according to claim 46 wherein the microareas are in the range of from 4 to 100 microns in size.
- 56. The improved process according to claim 40, wherein the support means adjacent the microareas is formed of a substantially transparent material.
- 57. The improved process according to claim 56, wherein the lateal wall means are dyed to enhance their capability of interrupting radiation.
- 58. In a process of producing an element useful in multicolor photography comprising
- forming support means areally extended along an axial plane comprised of bottom wall portions and lateral wall portions cooperating to form an array of microcells and
- sequentially positioning first, second, and third imaging compositions in first, second, and third interlaid sets of the microcells, respectively, the first, second, and third imaging compositions being chosen from among compositions which are responsive to or useful for absorbing light each in a different portion of the visible spectrum,
- the improvement comprising
- in forming the microcells, differentiating in at least one of depth, lateral extent along the axial plane, and orientation the microcells of the first set from the microcells of the remaining sets,
- positioning a radiation-sensitive material in the microcells,
- directing radiation toward the support means at an acute angle with respect to the axial plane, a portion of the radiation impinging on the radiation-sensitive material in the first set of the microcells while a remaining portion of the radiation is interrupted by the lateral walls to entirely shadow the radiation-sensitive material in the second and third sets of microcells,
- visibly differentiating the first and second sets of microcells as a function of exposure of the radiation-sensitive material, and
- selectively positioning the first imaging composition on the exposed bottom walls of the support in the first set of microcells.
- 59. The improved process according to claim 58, wherein the microcells of the first set are formed to be diamond-shaped with their major axes aligned in a single direction.
- 60. The improved process according to claim 58, wherein the microcells of the first set are formed to be rectangular with their major axes aligned in a single direction.
- 61. The improved process according to claim 58, wherein the first set of microcells are formed to be of lesser depth than the remaining sets of microcells.
- 62. The improved process according to claim 58, wherein, after initially directing radiation toward the support means at an acute angle with respect to the axial plane and before positioning the first imaging composition, the relationship of the support means to the initial direction of radiation is reversed 180.degree. in the axial plane and the step of directing radiation toward the support means at an acute angle with respect to the axial plane is repeated to selectively expose portions of the radiation-sensitive material in the first set of microcells which were shadowed during the first exposure.
- 63. In a process of producing an element useful in multicolor photography comprising
- forming support means areally extended along an axial plane comprised of bottom wall portions and lateral wall portions cooperating to form an array of microcells and
- sequentially positioning first, second, and third imaging compositions in first, second, and third interlaid sets of microcells, respectively, the first, second, and third imaging compositions being chosen from among compositions each responsive to or useful in absorbing light in a different protion of the visible spectrum,
- the improvement comprising
- in forming the microcells, differentiating the microcells of each set from the microcells of the remaining sets in at least one of depth, lateral extent along the axial plane, and orientation,
- positioning a radiation-sensitive material in the microcells,
- directing radiation toward the support means at an acute angle with respect to the axial plane to impinge a portion of the radiation on the radiation-sensitive material in the first set of the microcells while a remaining portion of the radiation is interrupted by the lateral wall portions to entirely shadow the radiation-sensitive material in the second and third sets of microcells,
- visibly differentiating the first set of microcells from the second and third sets of microcells as a function of exposure of the radiation-sensitive material,
- selectively positioning the first imaging composition on the exposed bottom walls of the support in the first set of microcells,
- directing radiation toward the support means at an acute angle with respect to the axial plane to impinge a portion of the radiation on the radiation-sensitive material in the second set of microcells while a remaining portion of the radiation is interrupted by the lateral walls to entirely shadow the radiation-sensitive material in the third set of microcells,
- visibly differentiating the second set of microcells from the third set of microcells as a function of exposure of the radiation-sensitive material, and
- selectively positioning the second imaging composition on the exposed bottom walls of the support in the second set of microcells.
- 64. The improved process according to claim 63, wherein radiation is subsequently directed toward the support means substantially perpendicular to the axial plane to expose the bottom walls of the third set of microcells and selectively positioning the third imaging composition on the exposed bottom walls of the support in the third set of microcells.
- 65. The improved process according to claim 58, 59, 60, 61, 62, 63, and 64, wherein the first, second, and third compositions are each comprised of radiation-sensitive means responsive to a different portion of the spectrum.
- 66. The improved process according to claim 65, wherein the radiation-sensitive means is silver halide.
- 67. The improved process according to claim 58, 59, 60, 61, 62, 63, and 64, wherein the first, second, and third compositions are each coprised of a subtractive primary dye or dye precursor.
- 68. The improved process according to claim 67, wherein the first, second, and third compositions are each comprised of a different subtractive primary dye or dye precursor capable of shifting between a mobile and an immobile form as a function of silver halide development.
- 69. The improved process according to claim 58, 59, 60, 61, 62, 63, or 64, wherein the first, second, and third compositions are each comprised of a different additive primary colorant means.
- 70. A process comprising
- forming support means areally extended along an axial plane comprised of bottom wall portions and lateral wall portions forming an interlaid pattern of at least two sets of microcells, the microcells of at least first and second sets each being relatively extended along a major axis parallel to the axial plane, the major axes of microcells of the same set being substantially aligned, and the major axes of microcells of the first and second sets being relatively oriented to intersect, whereby the microcells of at least the first and second sets can be uniquely addressed by radiation directed toward the support means at an acute angle with respect to the axial plane and substantially aligned with their major axes,
- positioning a radiation-sensitive material in the microcells,
- uniquely addressing the radiation-sensitive material in the first set of microcells with radiation substantially aligned with the major axes of the first set of microcells and at an acute angle with respect to the axial plane,
- visibly differentiating the first set of microcells from remaining microcells as a function of exposure of the radiation-sensitive material contained therein,
- selectively positioning a first radiation-sensitive material, colorant, or colorant precursor in the first set of microcells as a function of selective exposure of the radiation-sensitive material contained therein,
- uniquely addressing the radiation-sensitive material in the second set of microcells with radiation substantially aligned with their major axes and at an acute angle with respect to the axial plane,
- visibly differentiating the second set of microcells from remaining microcells as a function of exposure of the radiation-sensitive material contained therein, and
- selectively positioning a second radiation-sensitive material, colorant, or colorant precursor in the second set of microcells as a function of selective exposure of the radiation-sensitive material contained therein.
CROSS-REFERENCE TO RELATED APPLICATION(S)
This is a continuation-in-part of U.S. Ser. No. 196,947, filed Oct. 14, 1980, now abandoned.
US Referenced Citations (9)
Foreign Referenced Citations (3)
Number |
Date |
Country |
WO8001614 |
Aug 1980 |
WOX |
15027 OF |
Jan 1913 |
GBX |
456968 |
Nov 1936 |
GBX |
Non-Patent Literature Citations (1)
Entry |
James, Theory of Photographic Process, 4th Ed., Macmillan, 1977, p. 335. |
Continuation in Parts (1)
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Number |
Date |
Country |
Parent |
196947 |
Oct 1980 |
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