US3585965A - Development chamber - Google Patents

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US3585965A
US3585965A US789997A US3585965DA US3585965A US 3585965 A US3585965 A US 3585965A US 789997 A US789997 A US 789997A US 3585965D A US3585965D A US 3585965DA US 3585965 A US3585965 A US 3585965A
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discs
chamber
development chamber
development
atoms
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Alfred F Kaspaul
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Raytheon Co
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Hughes Aircraft Co
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    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G15/00Apparatus for electrographic processes using a charge pattern
    • G03G15/06Apparatus for electrographic processes using a charge pattern for developing

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  • the development chamber comprises first and second spaced discs around which a flexible medium to be US.
  • CL develo ed is wra ed around a major portion of the el H8/48 cumferences.
  • the medium to be developed has a latent image lllL l thereon which latent image is developed selective acquisi- 0 93, [ion of metal aoms from a vapor ource in accordance 94; 355/20, 27; l 7/107, 107-1, 105; the latent image character.
  • a vapor source is placed inside the 9 development chamber, between the discs, the discs rotate as the medium proceeds around the circumference exposing the [56] References cued latent images to the metal vapor, and upon completion of the UNITED STATES PATENTS development process moves away from the development 2,439,983 4/1948 Morgan et a] 1 18/49 chamber.
  • DEVELOPMENT CHAMBER BACKGROUND This invention is directed to a rotating development chamber, and particularly to a development chamber for the rapid and continuous development of recording media which have latent images thereon which may be developed into visible images by means of the selective deposition of metal atoms thereon.
  • a number of prior art processes for the recording of information and subsequent formation of visible images employ the selective deposition of various materials onto latent images. An example of this is found in A. F. Kaspaul, et al. US. Pat. No. 3,235,398, granted Feb. 15, 1966. A number of other inventions are directed to the same general type of process. These processes employ the selective deposition of metal atoms to create the visible image.
  • A. F. Kaspaul, et al., US. Pat. No. 3,140,143, granted July 7, 1964 describes the use of a metal chosen from Group "-8 of the periodic system, as a metal which can be employed with the particular substrate disclosed therein.
  • Selective deposition can be accomplished on suitable substrates by the employment of a variety of other materials as they are discharged from a boiler or any other suitable source. Additionally a metal choosen from Group 1-5 or magnesium, is suitable and can be employed in the same way. In other cases, the developer material is provided by the dissociation of a metal-containing compound such as silane. Furthermore, cadmium sulfide, lead sulfide, bismuth trioxide may be deposited in imagewise fashion to produce active elements for microcircuitry applications as described in A. F. and E. E. Kaspaul U.S. Pat. No. 3,333,984, granted Aug. 1, 1967. Additionally, whilethe three cited prior patents describe the selective deposition of metals, metal chalcogenides, etc., for image production, such deposition can be employed for other purposes, such as providing a conductive path, or the like.
  • the prior art teachings are directed to batch-type processing as well as toward continuous applications. However, they have not resulted in efficient employment of the vaporized materials at high processing speeds. Accordingly, in the prior art applications a sizeable fraction of the developer" is deposited within the development chamber rather than onto the substrate. Thus in continuous usage, material is wasted and frequent cleaning is necessary.
  • FIG. I is an isometric view of a recording and playback console employing the preferred embodiment of the development chamber of this invention.
  • FIG. 2 is an enlarged partial section taken generally along the line 2-2 of FIG. 1.
  • FIG. 3 is a partial section taken generally along the line 3-3 of FIG. 2.
  • FIGS. 4, 4b and 4c are graphs showing various conditions under which selective deposition of atoms and molecules will occur.
  • FIG. 5 is a schematic view of the development chamber of this invention showing development vapor paths.
  • FIG. 6 is a schematic view of a prior art development chamber showing development vapor paths.
  • FIG. 7 is a schematic view of the development chamber of this invention showing an optional wiper therein.
  • FIG. 8 is a section on the line 8-8 of FIG. 7.
  • FIG. 9 is a schematic view of another embodiment of the development chamber of this invention.
  • a recording and playback console 10 incorporates the development chamber 12 of this invention.
  • Console 10 includes housing spaces 14 and 16 for electronics. It is electrically connected and arranged to receive an electronically defined image which can be visually displayed on the face of cathode-ray tube 18.
  • the console receives images and sound in the form of electronic signals resulting from various sources commonly employed in conventional television practice.
  • the purpose of the console is to receive, record and to play back these signals in a desired line frequency.
  • An electron source 20 produces a modulated beam 22 in accordance with the input signals.
  • Beam 22 is focused and deflected by any conventional electrostatic or electromagnetic means, such as focusing and deflection means 24.
  • focusing and deflection means 24 rather than producing orthogonal scan, only lateral scan, corresponding to the horizontal scan on the image, is produced by the deflection means.
  • Housing 26 encloses the beam, and is pumped to a suitable lowpressure at the pump connections indicated for satisfactory beam performance. Draft tube 27 permits beam passage.
  • tape deck 28 includes a supply of recording tape on reel 30.
  • the tape 32 passes around exit guide roll 34 through slot 36 into a very narrow gap of chamber 38.
  • Capstan 40 rotates simultaneously with capstan 66 within chamber 38, wrapping the tape 32 around its circumference.
  • the width of slot 36, and the clearance around recording tape 32 as it moves around the capstan 40within chamber 38 is minimized to reduce pumping requirements.
  • Opening 42 in tape deck 28 permits beam 22 to impinge upon media 32 as it moves past opening 42 to thus create a latent image on the recording media. Since tape deck 28 and opening 42 are evacuated to different vacuum levels, the narrow spaces in chamber 38 are sufficient to maintain the desired pressures for each area.
  • FIG. 2 shows an arrangement whereby the gun areas may be held at :10 Torr with a 2 inch diffusion pump by connection 26 to port 39, whereas the recording/readout chambers are maintained at l" Torr with a 3 inch booster pump by connection to port ml.
  • Development chamber M and tape reel chambers of the tape deck 2% operate atZlO and 210 Torr, respectively, by use of forepumps connected to ports 453 and 45.
  • the media 32 passes into the stationary development chamber 44 in which the rotating development chamber 12 is located.
  • chamber 44 is closed by transparent cover 46 so that the progress of development can be observed.
  • Bearing post 48 is centrally mounted in recess 44 and hub 50 is rotatably mounted thereon.
  • Circular discs 52 and 54 are mounted upon hub 50 so as to rotate therewith.
  • upper disc 54 is conveniently removable from the hub and is transparent for visibility purposes.
  • Tape 32 passes around discs 52 and 54, so that the edges of the medium are engaged thereby, and the discs together with the hub, are rotated as the medium passes through the stationarydevelopment chamber 44.
  • Tape 32 engages around a substantial part of the circumference of the discs, as shown in FIG. 2, to define the rotating development chamber 12 enclosed by the medium and the discs.
  • Source 56 is the source of atoms and/or molecules for the development of the latent images contained within the medium 32.
  • Source 56 is conveniently a heated coil or mesh which is connected by leads 58 to the secondary of transformer 60. Energization of leads 62 to the primary of transformer 60 causes high current flow through the coil which forms source 56, thereby heating it to the proper temperature.
  • the coil or mesh is plated with the metal to be vaporized, such as zinc or cadmium, watts is sufficient to develop a 35 mm. tape at 36 inches/second, and one coil or mesh can have sufficient material to develop more than several thousand feet of tape.
  • other vapor sources may be employed, e.g., a small boiler could be used to supply the required vapor for many tape reels.
  • Source 56 is preferably positioned so that it is spaced equal distance from all points of the tape as the tape is wrapped around the discs to form the development chamber.
  • the developer source may be of any type and shape and will successfully operate as long as it is centrally located. Of course an eccentric positioning is possible if one adjusts the efflux pattern accordingly.
  • the now developed tape is transported to chamber M where it engages around capstan 66.
  • tape 32 passes through slot 68 ad around guide roll 70 to be wound on tape reel 72.
  • the readout gun 74 scanning across the tape on 19 capstan 66.
  • Electron gun 7% in housing 76 directs an electron beam 78 onto the image-carrying medium.
  • Focus and deflection means 80 scans the electron beam laterally across the tape as it moves past opening 82. As a result of electron impingement, photons are emitted in accordance with the image content of the medium. These photons are focused by mirror 84 onto photomultiplier 86.
  • Housing 76 is suitable evacuated for proper electron beam conditions, and the narrow spaces around the medium in chamber 64 permit the maintenance of a proper vacuum with minimal pumping equipment.
  • the usefulness of this invention may best be understood by exposing a given surface to a incident flux of atoms and/or molecules from a molecular oven or other vapor sources. Atoms and/or molecules will condense upon the surface, at first moving about it in random fashion. They are eventually captured by active sites to form a stable deposit, or reevaporated from the surface after a certain time has elapsed. At low incident rates, a certain number of atoms will be found upon the surface at any given time so that the equilibrium concentration is reached as soon as the reevaporation rate equals the incident flux. At equilibrium,
  • B surface coverages of 6;lO'
  • FIG. 7 shows a simple solution for the prevention of random nucleation centers in the rotating development chamber.
  • the recording tape containing the latent images forms a substantial portion of the development chamber and is therefore exposed to the incident flux of zinc atoms as long as it surrounds the two glass discs and the developer source. During this time interval, atoms and/or molecules will condense and reevaporate from its surface, which has, with the exception of the latent images, quite similar surface properties as those of the glass discs. Hence no condensation occurs upon the background of the medium.
  • the tape enters the rotating development chamber on the left and is immediately exposed to a uniform zinc flux.
  • the tape will take a certain time for even the most energetic centers to take full control over the deposition process, faithfully reproducing the desired information.
  • the time interval from the first exposure of the tape to the zinc vapor to the onset of barely visible images, ranges from about 0.25 to 0.75 of the total time spent in the development chamber.
  • FIGS. 5 ad 6 show two extremes, in each case utilizing a filament-type zinc source.
  • the FIG. 6 is typical for prior art arrangements and large incident rates are required to produce visible images in the shortest possible time. About 80 percent of the atoms may be lost, at TV-recording rates, whereas by using the rotating development chamber, all reevaporating atoms are collected, eventually, by other portions of the tape.
  • a modified development system may be constructed whereby a uniform zinc flux is established over a length of tape.
  • this is not a simple approach and requires not only a large area source, as is shown in FIG. 9, but also a sizable backup surface.
  • this zinc reflector Since this zinc reflector" is not renewed it may become coated in time, and adsorbs all the zinc available. In comparison, the dead area" in the rotating chamber of this invention is quite small and the developer flux incident upon it is far below critical. Furthermore, the two rotating glass discs as well as the hub may be fitted with a stationary wiper as shown in F I08. 7 and 8. This felt-type rectangular wiper block 98 may be soaked in a suitable organic liquid of low free surface energy, thus providing continuous protection for the wiped surface from zinc deposition. The kind of recording medium is not critical. As a matter of fact, anything that has a controlled variation of the surface free energy upon it may be developed in this manner. The
  • preferred media for electron beam recording/readout in nearreal-time comprise mainly of photoconductive and photoemissive pigments combined with a nucleation inducing compound in a suitable binder.
  • Decomposable compounds yielding nucleation centers of desired configurations upon electron, photon or ion bombardment may also be utilized.
  • Means to develop latent images on an indefinite length moving web comprising:
  • wiper means extending between said discs at an open area thereof with respect to said web whereby said discs are wiped clean of developer material.
  • first and second closure plates are of such material and are maintained at such a temperature that metal atoms at a suitable metal atom rate for imagewise deposition of metal atoms on the medium do not form a stable film on said first and second closure plates.

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Non-Silver Salt Photosensitive Materials And Non-Silver Salt Photography (AREA)
  • Physical Vapour Deposition (AREA)
  • Luminescent Compositions (AREA)

Abstract

The development chamber comprises first and second spaced discs around which a flexible medium to be developed is wrapped around a major portion of the disc circumferences. The medium to be developed has a latent image thereon, which latent image is developed by selective acquisition of metal atoms from a vapor source, in accordance with the latent image character. A vapor source is placed inside the development chamber, between the discs, the discs rotate as the medium proceeds around the circumference exposing the latent images to the metal vapor, and upon completion of the development process moves away from the development chamber.

Description

United States Patent [72] Inventor Allred I". Kasplul 2,768,098 10/1956 Hoppe 118/49 X Malibu, Calif. 2,948,261 8/1960 McGraw, Jr 118/49 1233 1 Primary Examiner-Morris Kaplan 1 Panama! June 22 1971 Attorneys-James K. Haskell and Allen A. Dlcke, Jr. [73] Assiguee Hughes Aircraft Company Culver City, Calll.
P N [54] rg tfigg fi ABSTRACT: The development chamber comprises first and second spaced discs around which a flexible medium to be US. CL develo ed is wra ed around a major portion of the el H8/48 cumferences. The medium to be developed has a latent image lllL l thereon which latent image is developed selective acquisi- 0 93, [ion of metal aoms from a vapor ource in accordance 94; 355/20, 27; l 7/107, 107-1, 105; the latent image character. A vapor source is placed inside the 9 development chamber, between the discs, the discs rotate as the medium proceeds around the circumference exposing the [56] References cued latent images to the metal vapor, and upon completion of the UNITED STATES PATENTS development process moves away from the development 2,439,983 4/1948 Morgan et a] 1 18/49 chamber.
l b Z\ \\2 \\7\ q a i \z '/r //5 1 \\I I I I I l PATENTED JUNZZIHYI $585,965
sum 1 OF 7 Alfred F. Kuspoul,
INVENTOR.
ALLEN A DICKE, Jr.,
AGENT.
PATENTEU JUNE 2 I97l SHEET 2 OF 7 Alfred F. Kospuul,
INVENTOR ALLEN A. DICKE, Jr.,
AGENT.
PATENTEU JUH22 1911 SHEET 3 OF 7 smow eoopns ;o Jequm Alfred F. Kospoul,
INVENTOR.
ALLEN A. DICKE, Jr.,
AGENT.
PATENIEU JUN22 19?:
Fig. 4b.
SHEET [1F 7 I I I I I I l I I w l g I I I l I- I I I I swow eoopns ;o JBQUJHN Alfred F KospouI INVENTOR.
ALLEN A. mom; Jr,
AGENT.
PATENTEH JUH22 um SHEET 5 0F 7 Higher flux rate Intermediate flux rate F 40' Lower flux rate v Time UniformiMeLcQ Flux Alfred F. Kuspoul,
INVENTOR.
ALLEN A. DICKE, Jr.
AGENT PATENIED JUH22 IHYI SHEET 5 OF 7 Alfred F. Kuspuul,
INVENTOR.
BYv
ALLEN A. DICKE, Jr,
AGENT.
PATENTED JUH22|97| SHEET 7 0F 7 Alfred F. Kospoul,
INVENTOR.
ALLEN A. DICKE, Jr,
AGENT.
DEVELOPMENT CHAMBER BACKGROUND This invention is directed to a rotating development chamber, and particularly to a development chamber for the rapid and continuous development of recording media which have latent images thereon which may be developed into visible images by means of the selective deposition of metal atoms thereon.
A number of prior art processes for the recording of information and subsequent formation of visible images employ the selective deposition of various materials onto latent images. An example of this is found in A. F. Kaspaul, et al. US. Pat. No. 3,235,398, granted Feb. 15, 1966. A number of other inventions are directed to the same general type of process. These processes employ the selective deposition of metal atoms to create the visible image. A. F. Kaspaul, et al., US. Pat. No. 3,140,143, granted July 7, 1964, describes the use of a metal chosen from Group "-8 of the periodic system, as a metal which can be employed with the particular substrate disclosed therein. Selective deposition can be accomplished on suitable substrates by the employment of a variety of other materials as they are discharged from a boiler or any other suitable source. Additionally a metal choosen from Group 1-5 or magnesium, is suitable and can be employed in the same way. In other cases, the developer material is provided by the dissociation of a metal-containing compound such as silane. Furthermore, cadmium sulfide, lead sulfide, bismuth trioxide may be deposited in imagewise fashion to produce active elements for microcircuitry applications as described in A. F. and E. E. Kaspaul U.S. Pat. No. 3,333,984, granted Aug. 1, 1967. Additionally, whilethe three cited prior patents describe the selective deposition of metals, metal chalcogenides, etc., for image production, such deposition can be employed for other purposes, such as providing a conductive path, or the like.
The prior art teachings are directed to batch-type processing as well as toward continuous applications. However, they have not resulted in efficient employment of the vaporized materials at high processing speeds. Accordingly, in the prior art applications a sizeable fraction of the developer" is deposited within the development chamber rather than onto the substrate. Thus in continuous usage, material is wasted and frequent cleaning is necessary.
SUMMARY In order to aid in the understanding of this invention, it can be stated in essentially summary form that it is directed to a rotating development chamber, which chamber is formed in part by the medium to be developed. The development chamber is also formed in part by chamber-defining structures. Vapor is present in the chamber and the vapor flux, in combination with the surface condition of the media and the other chamber-defining walls, is such that stable, selective deposition occurs only upon the media.
Accordingly, it is an object of this invention to provide a development chamber which is arranged for the development of various media by the deposition thereon of selected materials to form a visible image faithfully reproducing the informa tion stored in the latent, invisible, images of the media. It is a further object of this invention to provide a development chamber wherein the portion of the chamber which is formed by other than the media is at such conditions, and the developing vapor flux is adjusted to such a rate that stable deposition does not take place on any of the walls of the chamber except the wall formed by the medium. It is still another object of this invention to provide a development chamber which is formed of first and second spaced discs and the medium embraces a large portion of the circumference of the discs to define the development chamber therein. It is still another object to provide a structure wherein media can be continuously developed by passing it circumferentially around a development chamber defined by a pair of spaced discs and by the medium so that media can be continuously moved through a development zone. It is still another object of this invention to provide a development chamber wherein continuous development is accomplished at nearly percent efficient Other objects and advantages of this invention will become apparent from a study of the following portion of the specification, the claims and the attached drawings.
BRIEF DESCRIPTION OF THE DRAWINGS S FIG. I is an isometric view of a recording and playback console employing the preferred embodiment of the development chamber of this invention.
FIG. 2 is an enlarged partial section taken generally along the line 2-2 of FIG. 1.
FIG. 3 is a partial section taken generally along the line 3-3 of FIG. 2.
FIGS. 4, 4b and 4c are graphs showing various conditions under which selective deposition of atoms and molecules will occur.
FIG. 5 is a schematic view of the development chamber of this invention showing development vapor paths.
FIG. 6 is a schematic view of a prior art development chamber showing development vapor paths.
FIG. 7 is a schematic view of the development chamber of this invention showing an optional wiper therein.
FIG. 8 is a section on the line 8-8 of FIG. 7.
FIG. 9 is a schematic view of another embodiment of the development chamber of this invention.
DESCRIPTION A recording and playback console 10 incorporates the development chamber 12 of this invention. Console 10 includes housing spaces 14 and 16 for electronics. It is electrically connected and arranged to receive an electronically defined image which can be visually displayed on the face of cathode-ray tube 18. In other words, the console receives images and sound in the form of electronic signals resulting from various sources commonly employed in conventional television practice. The purpose of the console is to receive, record and to play back these signals in a desired line frequency.
An electron source 20 produces a modulated beam 22 in accordance with the input signals. Beam 22 is focused and deflected by any conventional electrostatic or electromagnetic means, such as focusing and deflection means 24. However, rather than producing orthogonal scan, only lateral scan, corresponding to the horizontal scan on the image, is produced by the deflection means. Housing 26 encloses the beam, and is pumped to a suitable lowpressure at the pump connections indicated for satisfactory beam performance. Draft tube 27 permits beam passage.
As is seen in FIG. 2, tape deck 28 includes a supply of recording tape on reel 30. The tape 32 passes around exit guide roll 34 through slot 36 into a very narrow gap of chamber 38. Capstan 40 rotates simultaneously with capstan 66 within chamber 38, wrapping the tape 32 around its circumference. The width of slot 36, and the clearance around recording tape 32 as it moves around the capstan 40within chamber 38 is minimized to reduce pumping requirements. Opening 42 in tape deck 28 permits beam 22 to impinge upon media 32 as it moves past opening 42 to thus create a latent image on the recording media. Since tape deck 28 and opening 42 are evacuated to different vacuum levels, the narrow spaces in chamber 38 are sufficient to maintain the desired pressures for each area.
Differential pumping of the recording/readout chambers and the respective gun areas is preferably utilized to minimize the size requirements of the vacuum equipment. FIG. 2 shows an arrangement whereby the gun areas may be held at :10 Torr with a 2 inch diffusion pump by connection 26 to port 39, whereas the recording/readout chambers are maintained at l" Torr with a 3 inch booster pump by connection to port ml. Development chamber M and tape reel chambers of the tape deck 2% operate atZlO and 210 Torr, respectively, by use of forepumps connected to ports 453 and 45.
From chamber 33, the media 32 passes into the stationary development chamber 44 in which the rotating development chamber 12 is located. As seen in FIG. 3, chamber 44 is closed by transparent cover 46 so that the progress of development can be observed. Bearing post 48 is centrally mounted in recess 44 and hub 50 is rotatably mounted thereon. Circular discs 52 and 54 are mounted upon hub 50 so as to rotate therewith. Preferably, upper disc 54 is conveniently removable from the hub and is transparent for visibility purposes. Tape 32 passes around discs 52 and 54, so that the edges of the medium are engaged thereby, and the discs together with the hub, are rotated as the medium passes through the stationarydevelopment chamber 44. Tape 32 engages around a substantial part of the circumference of the discs, as shown in FIG. 2, to define the rotating development chamber 12 enclosed by the medium and the discs.
Source 56 is the source of atoms and/or molecules for the development of the latent images contained within the medium 32. Source 56 is conveniently a heated coil or mesh which is connected by leads 58 to the secondary of transformer 60. Energization of leads 62 to the primary of transformer 60 causes high current flow through the coil which forms source 56, thereby heating it to the proper temperature. When the coil or mesh is plated with the metal to be vaporized, such as zinc or cadmium, watts is sufficient to develop a 35 mm. tape at 36 inches/second, and one coil or mesh can have sufficient material to develop more than several thousand feet of tape. Of course, other vapor sources may be employed, e.g., a small boiler could be used to supply the required vapor for many tape reels. Source 56 is preferably positioned so that it is spaced equal distance from all points of the tape as the tape is wrapped around the discs to form the development chamber.
The developer source may be of any type and shape and will successfully operate as long as it is centrally located. Of course an eccentric positioning is possible if one adjusts the efflux pattern accordingly.
After leaving stationary development chamber 44, the now developed tape is transported to chamber M where it engages around capstan 66. After leaving capstan 66, tape 32 passes through slot 68 ad around guide roll 70 to be wound on tape reel 72. If reading of the image is required immediately following recording and development it may be accomplished with the readout gun 74 scanning across the tape on 19 capstan 66. Electron gun 7% in housing 76 directs an electron beam 78 onto the image-carrying medium. Focus and deflection means 80 scans the electron beam laterally across the tape as it moves past opening 82. As a result of electron impingement, photons are emitted in accordance with the image content of the medium. These photons are focused by mirror 84 onto photomultiplier 86. The image is thus returned to an electronic signal and can be rebroadcast in a different line frequency and/or cathode-ray tube 88. Housing 76 is suitable evacuated for proper electron beam conditions, and the narrow spaces around the medium in chamber 64 permit the maintenance of a proper vacuum with minimal pumping equipment.
The usefulness of this invention may best be understood by exposing a given surface to a incident flux of atoms and/or molecules from a molecular oven or other vapor sources. Atoms and/or molecules will condense upon the surface, at first moving about it in random fashion. They are eventually captured by active sites to form a stable deposit, or reevaporated from the surface after a certain time has elapsed. At low incident rates, a certain number of atoms will be found upon the surface at any given time so that the equilibrium concentration is reached as soon as the reevaporation rate equals the incident flux. At equilibrium,
n =,=N A exp (-Pad/RT) log n,/N,, log A (0.434) dud/RT n,= lncident flux, [atoms cm. sec."]
n,= Re emitted atoms, [atoms cm." sec."]
N Number of surface adsorbed atoms, [atoms cm."]
A Frequency constant -10" for most metals 2 Estimated heat of absorption, [KcaL 'mole" R =Gas constant [1.987 cal. deg mole"] T-Temperature in degree Kelvin [K.] Using zinc for the incident atoms and a glass surface held at 300' K. as the receptor,
m 12.3 Using this value, suFface concentrations of 10 or 10 atoms/cm. are obtained with incident rates of 10" or 10' atoms/cm. see. it may be assumed that up to surface coverages of 6;lO' (B=N,, /N,,, N,,, number of possible surface sites in an orderly lattice) no stable twins or even triplets will be produced which have a much longer lifetime than single atoms, thus all atoms will eventually leave the surface, especially upon cessation of the incident flux. In FIG. 4a, curves and 92 indicate this for the two concentrations of 10 and 10" atoms/cm, respectively, Hence the two glass discs of the development chamber should be free of zinc deposits as long as the surface coverage is kept below 10'", and spurious nucleation centers are avoided. FIG. 7 shows a simple solution for the prevention of random nucleation centers in the rotating development chamber.
As previously indicated, the recording tape containing the latent images forms a substantial portion of the development chamber and is therefore exposed to the incident flux of zinc atoms as long as it surrounds the two glass discs and the developer source. During this time interval, atoms and/or molecules will condense and reevaporate from its surface, which has, with the exception of the latent images, quite similar surface properties as those of the glass discs. Hence no condensation occurs upon the background of the medium.
However, electrons previously impinged upon the medium have created latent images characterized by areas of much greater heat of adsorption for zinc. At an incident flux of about 10" atoms/cm. sec., these invisible images develop into visible images, in less than 1 second, if one assumes that Q is about 12 K. cal./mole for an average portion of the latent image, thus log log nJN 5.5 The corresponding surface concentration amounts to nearly 10" atoms/cm. (6*=l0) which is much too large to maintain equilibrium condition, hence rapid formation of twins, triplets and stable cluster occurs and continuous film growth is only a matter of time.
Because the previous electron beam incidence upon the tape has modulated the number of nucleation sites, their effective energy and distribution, P varies with the information content and one obtains a time dependence of the onset of permanent condensation. This is illustrated in FIG. 4b by curves 94 and 96, assuming a constant incident rate. Curve 94 represents a large exposure to electrons, curve 96 a smaller amount of irradiation, and curve 92 the unexposed background of the tape. The critical surface concentration of about l0 atoms/cm. was found experimentally; at this point the reevaporation rate drops rapidly to zero and every incoming atom must be captured. By carefully controlling the zinc flux and the development speed, all zinc atoms are eventually deposited upon the recording tape without any loss of material to adjacent areas. Furthermore, by the very nature of the rotating development chamber, any rise of the incident rate does not precipitate the deposition of zinc on unwanted areas, because the process is self-regulating. This is best explained by FIG. 40.
As shown, the tape enters the rotating development chamber on the left and is immediately exposed to a uniform zinc flux. Depending upon the image content it will take a certain time for even the most energetic centers to take full control over the deposition process, faithfully reproducing the desired information.
For all practical purposes, the time interval, from the first exposure of the tape to the zinc vapor to the onset of barely visible images, ranges from about 0.25 to 0.75 of the total time spent in the development chamber.
Normally the onset of visible condensation is chosen to be at about midpoint in the development chamber by adjusting the incident rate accordingly, hence a rise or fall of the number of incident atoms due to various demands of the tape will only shift this point either forward or to the rear without affecting anything else except the final optical density of the images. Curves 90 show the background at the several flux rates while the upper curves show the image deposition at the several flux rates. If unexposed tapes are fed into a development chamber while maintaining a steady efflux from the developer source, the number of available zinc atoms must increase within the volume of the chamber resulting in an excessive incident rate. With the rare exception of the rotating chamber configuration, autonucleation proceeds indiscriminately in the system and suddenly zinc atoms will condense everywhere. At excessive incident rates, the rotating chamber seldom becomes coated and the tape will always pick up the zinc even though it has not been exposed to electrons. This is made possible by the most favorable arrangement whereby the tape circles the developer source.
FIGS. 5 ad 6 show two extremes, in each case utilizing a filament-type zinc source. The FIG. 6 is typical for prior art arrangements and large incident rates are required to produce visible images in the shortest possible time. About 80 percent of the atoms may be lost, at TV-recording rates, whereas by using the rotating development chamber, all reevaporating atoms are collected, eventually, by other portions of the tape. Of course, a modified development system may be constructed whereby a uniform zinc flux is established over a length of tape. However, this is not a simple approach and requires not only a large area source, as is shown in FIG. 9, but also a sizable backup surface. Since this zinc reflector" is not renewed it may become coated in time, and adsorbs all the zinc available. In comparison, the dead area" in the rotating chamber of this invention is quite small and the developer flux incident upon it is far below critical. Furthermore, the two rotating glass discs as well as the hub may be fitted with a stationary wiper as shown in F I08. 7 and 8. This felt-type rectangular wiper block 98 may be soaked in a suitable organic liquid of low free surface energy, thus providing continuous protection for the wiped surface from zinc deposition. The kind of recording medium is not critical. As a matter of fact, anything that has a controlled variation of the surface free energy upon it may be developed in this manner. The
preferred media for electron beam recording/readout in nearreal-time comprise mainly of photoconductive and photoemissive pigments combined with a nucleation inducing compound in a suitable binder. Decomposable compounds yielding nucleation centers of desired configurations upon electron, photon or ion bombardment may also be utilized.
This invention having been described in its preferred embodiment, and an alternative embodiment also described, it is clear that it is susceptible to numerous modifications and embodiments within the ability of those skilled in the art and without the exercise of the inventive faculty. Accordingly, the scope of this invention is defined by the scope of the following claims.
What is claimed is:
1. Means to develop latent images on an indefinite length moving web comprising:
a pair of axially aligned rotatable discs;
means to feed said web in a path to peripherally engage said discs so as to form a substantially closed chamber with the image areas on said web facing inwardly;
said moving web thereby rotating said discs;
a source of vaporized developer material disposed within said chamber; and
wiper means extending between said discs at an open area thereof with respect to said web whereby said discs are wiped clean of developer material.
2. The development chamber of claim 1 wherein at least one of said discs is transparent so that the development activity within said development chamber can be visually observed from exteriorl of said develo ment chamber. I
3. The deve opment cham er of claim 1 wherein said discs are rotatably mounted by being mounted upon a rotatable hub, and said wiper engages said hub to wipe said hub as said hub rotates with said discs.
4. The development chamber of claim 1 wherein said wiper carries an organic liquid thereon having low free surface energy to deposit organic liquid on said discs as said wiper wipes said discs to inhibit deposition of atoms on said discs.
5. The development chamber of claim 1 wherein said first and second closure plates are of such material and are maintained at such a temperature that metal atoms at a suitable metal atom rate for imagewise deposition of metal atoms on the medium do not form a stable film on said first and second closure plates.
H050 UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3 585 965 Dated June 22 I 1971 Alfred F. Kaspaul Inventor(s) It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:
!" Column 2, line 74 after "connection, delete "26 (Page 6, line 25) Column 3, line 1, "10 should be -lO (Page 6 line 27) Column 3, line 3, "10 should be "10' (Page 7, line 1) Column 3, line 48, after "on", delete "19''. (Page 8, line 18) Column 3, line 73, "n should be n n.-. (Page 9, line 17) e e l Column 3, line 75, "cm sec should be cm 'sec (Page 9 line 20) Column 4, line 1, "cm sec should be cm sec (Page 9, line 21).
Column 4, line 2, "cm should be cm (Page 9 line 22) Column 4 line 4 "mole should be mole (Page 9, line 24) Column 4, line 5, "deg mole should be deg mole (Page 9, line 25) Column 4, line 13, "10 should be --10' (Page 10, line 8) Column 4, line 21, "10 should be --10' (Page 10, line 16) L. (Continued on Page 2) Pa e 2 of 2. $69) UNITED STATES PATENT OFFICE g CERTIFICATE OF CORRECTION Patent N 3 I585! 5 Dated June 22, 1971 Alfred F. Kaspaul It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:
"l0 should be -l0 Column 4, line 43, (Page 11, line 11) Signed and sealed this 20th day of June I972.
(SEAL) Attest EDWARD FLFLETCHEHJR. ROBERT GOT'ISCHALK Attesting Officer Commissioner of Patents

Claims (5)

1. Means to develop latent images on an indefinite length moving web comprising: a pair of axially aligned rotatable discs; means to feed said web in a path to peripherally engage said discs so as to form a substantially closed chamber with the image areas on said web facing inwardly; said moving web thereby rotating said discs; a source of vaporized developer material disposed within said chamber; and wiper means extending between said discs at an open area thereof with respect to said web whereby said discs are wiped clean of developer material.
2. The development chamber of claim 1 wherein at least one of said discs is transparent so that the development activity within said development chamber can be visually observed from exteriorly of said development chamber.
3. The development chamber of claim 1 wherein said discs are rotatably mounted by being mounted upon a rotatable hub, and said wiper engages said hub to wipe said hub as said hub rotates with said discs.
4. The development chamber of claim 1 wherein said wiper carries an organic liquid thereon having low free surface energy to deposit organic liquid on said discs as said wiper wipes said discs to inhibit deposition of atoms on said discs.
5. The development chamber of claim 1 wherein said first and second closure plates are of such material and are maintained at such a temperature that metal atoms at a suitable metal atom rate for imagewise deposition of metal atoms on the medium do not form a stable film on said first and second closure plates.
US789997A 1969-01-09 1969-01-09 Development chamber Expired - Lifetime US3585965A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3735728A (en) * 1971-12-01 1973-05-29 Andvari Inc Apparatus for continuous vacuum deposition

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2439983A (en) * 1944-01-15 1948-04-20 Libbey Owens Ford Glass Co Means for thermally evaporating various materials in vacuums for coating purposes
US2768098A (en) * 1950-09-12 1956-10-23 Siemens Ag Method and apparatus for precipitating metal from the vaporous state onto plates, particularly for the production of selenium coated rectifier plates
US2948261A (en) * 1956-12-07 1960-08-09 Western Electric Co Apparatus for producing printed wiring by metal vaporization

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2439983A (en) * 1944-01-15 1948-04-20 Libbey Owens Ford Glass Co Means for thermally evaporating various materials in vacuums for coating purposes
US2768098A (en) * 1950-09-12 1956-10-23 Siemens Ag Method and apparatus for precipitating metal from the vaporous state onto plates, particularly for the production of selenium coated rectifier plates
US2948261A (en) * 1956-12-07 1960-08-09 Western Electric Co Apparatus for producing printed wiring by metal vaporization

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3735728A (en) * 1971-12-01 1973-05-29 Andvari Inc Apparatus for continuous vacuum deposition

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CH499137A (en) 1970-11-15
SE363953B (en) 1974-02-04
FR2027978A1 (en) 1970-10-02
BE743911A (en) 1970-05-28
DE1963119A1 (en) 1970-07-23

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