DE2228265A1 - Recording method - Google Patents

Description

ADVICE AGENCIES

DR. E. WIEGAND DIPL-ING. W. NIEMANN 2228265

DR. M. KÖHLER DIPL-ING. C. GERNHARDT

MÖNCHEN HAMBURG

phone: 5.5547 «8000 monks en June 15, 9, 1972

TELEGRAMS: KARPATENT NUSSBAUMSTRASSE 10

W 41 180/72 K / Yes

Fuji Photo Film Co., Ltd.
Minami Ashigara ~ Shi, "
Kanagawa (Japan)

Recording method

The invention is concerned with a recording method. In particular, the invention relates to a method to form permanent images by simply exposing metal halides to light without that a chemical treatment is carried out.

The subject matter of the invention is a recording process in which an image-wise crystal layer of metal halides an energy with an intensity that satisfies the equation

D = KI ⁿ

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where D is the optical density, K is a constant, I is the intensity is the exposure energy and η is 1 or more.

So far, the formation of images has been carried out according to processes, whereby light-sensitive materials, such as a silver halide emulsion or a diazo photosensitive hater exposed to light and were fixed. In particular, methods using silver halide emulsion ions are excellent Recording methods with respect to the obtained images of a high sensitivity and a high resolution.

In the previous recording methods, images could not be obtained, if a chemical or physical treatment has been carried out. Furthermore, the recording element must be treated in the dark, until the images are formed, since the recording be em ent a sensitization by visible rays and rays a with a wavelength close to the visible rays.

In addition, there have been recording methods that are completely different from the above methods are suggested. For example, H.R. Tubbs a Recording method introduced wherein one of metal halide compounds or chalcogen compounds built up filler material is used, for which on The Journal of Photographic Sciences, Volume 17, pages 162-169 (1969) is referenced.

The content of the above report is that images are obtained with a high resolution v / ground if visible rays with less than 52OO & or ultraviolet rays deposited on one Lead ijoclide film is applied at I60 to 22 (73,

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cta the exposed parts change their color from yellowish orange to change colorless, and that images with a resolution above 1 micron can be obtained if one metallic silver film and one on a glass slide applied lead iodide filra to a light with 1 j / cm " are exposed at room temperature, but the images will deteriorate if they are not covered with an overlay film.

As a result of numerous investigations into methods for recording images in the light without carrying out a chemical or physical treatment , a recording method has been found within the scope of the invention which is completely different from the methods specified above.

One object of the invention is a new one Recording method. A second object of the invention is a recording method for forming images with only one exposure or odor Exposure. A third object of the invention is a recording method carried out in light can be; A fourth object of the invention is a recording method for forming images with a high contrast. Another object of the invention is a recording method, in which multiple recording can be carried out.

In the course of numerous studies to achieve the above-mentioned tasks, the Invention found the fact that metal halides do not undergo semi-permanent sensitization by excitation with a light intensity below a threshold value, but permanent images through Am-eguijr; with a light intensity above the vorf-tohend c.ngogebenem form fourth.

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It has thus been found that metal halides have a property which satisfies the following equation:

D = KI ⁿ (n> i)

where D is the optical density, K is a constant, for example 6 χ 10 for lead iodide, I is the intensity of the exposure, ie the energy per square unit (for example nJ / cm) is a number, generally 1 <n <2, can be used.

In Figures 1 and 2 graphs are given showing the relationship between the density of the show images obtained with the recording method according to the invention and the applied energy.

The above relationship shows a phenomenon common to the usual photosensitive materials is not observed.

The strongest feature of the phenomenon in the context of the present invention is that the density is at 0 remains even if energy is applied until the energy reaches a specific value and the density occurs when the energy has reached the threshold. That is why the slope of the through D = KI (n> i) 'specified slope of the curve large. This Feature gives excellent effects in the method of the present invention.

The metal halides that can be used in the process according to the invention include lead iodide, lead chloride, Lead bromide, silver iodide, silver bromide, copper iodide, Copper bromide and mercury iodide, which as single crystals, Multicrystals, mixed crystals or as a deposited film or dispersed layer on a support, be used.

As the metals of the metal halides, those having numerous electrons are preferable. The strongest

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preferred metal halides include those of lead and mercury. They are chosen according to the task because the sensitization energy intensity in the order of metal iodides, metal bromides and metal chlorides increases, with the preferred metal halides being the metal iodides.

All energy sources can be used as an energy source for image formation, provided that the electromagnetic waves have the necessary light intensity range to cause the non-linear appearance of the substances. For example, lasers such as Ruby lasers (wavelength 6943 Å) can be used. If, for example, a dispersion film of lead iodide powder also has no absorption in a wavelength range greater than 520 millimicrons, it forms black images when it is image-wise attached to a Giant Rubjr laser light with a maximum peak strength of 30 \ J (half-width 15 n-sec) Exposed to room temperature. Since the metal halides each have a specific absorption wavelength, it is preferred to use light having a wavelength larger than the specific absorption wavelength. The dispersion film of the metal halide can be formed on a support such as glass, metals or plastic films using conventional methods. The dispersion layer can be prepared by dispersing the metal halide in an aqueous solution of a common binder such as gelatin, polyvinyl alcohol, polystyrene and polyvinyl chloride. The amount of the metal halide in the dispersion layer is not critical, but is preferably about 1 m-mol per 1 g of the binder. The metal halide can be used down to 0.25 m-mol per 1 g of binder. When using the deposited film or the dispersion layer as a recording

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tion element, it is preferred that the film or the Layer is greater than 1 micron thick, preferably up to 100 microns thick. Since according to the invention Method High contrast and high resolution images by application only of energy with a specific value can be obtained, it is possible to record multiple times to execute. For example, the multiple recording can be made by an Ilulti-Photon method by concentration of light and taking advantage of the non-linear effect of the recording material to form images at different depths in the photosensitive layer, "continues all treatments up to the formation of the images can be carried out at room temperature in the light v / earth. In addition, it has an advantage that permanent images can be obtained without the need for treatments, how development, fixation and stabilization are carried out.

The method according to the invention can be used as a result for the production of copier masks and numerous copier systems, such as photoresistors, negative or positive films, Microfilming and information gathering applied.

The following examples serve to further illustrate the invention.

example 1

Lead iodide was made up of gelatin in an aqueous solution dispersed to a concentration of 7.5 mol / g gelatin. The solution was applied to the surface of a glass slide applied and at room temperature under reduced pressure with the formation of a lead iodide layer of

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40 / u starch dried.

When the obtained recording element was imagewise exposed to a giant pulse Poiby laser (maximum peak strength 50 I ¹ M, half-width 20 n-sec), the exposed portions turned black and formed a recording image.

The apparent density of the exposed parts was determined using a Macbeth densitometer. The result obtained by plotting the relationship between energy and density is shown in FIG. In this way, the constant K for lead iodide can be calculated mathematically from the line shown in FIG can be obtained.

A curve with a large slope results from the values in FIG. 1, i.e. images with a high contrast is obtained for the first time using an energy of 25 mJ.

• Example 2

Images were formed in the same manner as in Example 1 except that a micron lead iodide layer was formed by dispersing lead iodide powder in an aqueous solution of gelatin so as to give a concentration of 1.05 x * \ 0 ~ hol / g of gelatin which was applied to a glass plate and dried. The results obtained are shown in FIG.

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Claims (5)

Claims MJ) recording method, characterized that imagewise a crystal layer of metal halides with an energy of one Intensity, which is the equation D = KI ⁿ where D is the optical density, K is a constant, I is the intensity of exposure energy and η is the number 1 or greater means being exposed. 2) method according to claim 1, characterized that as metal halides lead iodide, lead chloride, lead bronide, silver iodide, silver broraide, Copper iodide, copper bromide, mercury iodide or Mixtures thereof can be used. 3) Method according to claim 1 or 2, characterized characterized in that a crystal layer applied to a support is used. 4) Method according to claim 3 »characterized that the crystal layer is dispersed in a binder. 5) Method according to claim 4, d.a characterized by that used as a binder gelatin, polyvinyl alcohol, polystyrene or polyvinyl chloride will.' 209853/1028 Blank page