DE1813920C - Process for producing photographic images - Google Patents

Description

5. The method according to claim 1, characterized for a color-providing oxidation reaction to one shows that a hydrogen-visible image is developed as the peroxy compound, the metal peroxide being used in aqueous solution. germ pattern with catalytically decomposable on the germs

0. The method according to claim 1, characterized in that peroxy compounds are marked in the presence of one or more that the treatment with peroxy compounds 45 rer reaction components for a color fertilization is treated in the presence of dye precursors oxidation reaction, takes place, which under oxidative coupling to dye- The process according to the invention is characterized by

substances react. a significantly improved economic efficiency, because

7. The method according to claim 6, characterized in that the treatment with Peroxyverbin'- 50 metal salts, in particular silver salts, is only relative fertilize in the presence of photographic, small amounts of color. The through the donating developers of the p-phenylenediamine series process according to the invention have obtained images and photographic color couplers. excellent quality; regarding image sharpness

they are in many cases superior to images obtained by conventional 55 methods. Used

one photosensitive recording materials that

conventional superhalide emulsion layers are achieved by the inventive

The Invention! «, A novel method for the method has a significantly higher sensitivity, since Production of photo) graphic images by catalytic, even weakly exposed image areas, which are practically invisible in the case of conventional decomposition of peroxy compounds in image-wise vertical processing, shared precious metal germs. can be developed into a visible image.

For the production of photographic images, the photochemical decomposition of precious metal

the most diverse processes are known. Of the highest connections to the underlying metals The conventional 65 per se have long been known of practical importance. Thus, gold-binding photographic processes, in which silver fertilizes with the formation of gold nuclei, are photochemical halide emulsion layers decomposed with conventional deconstruction. ' The same applies to precious metal compounds Winding substances are developed. In particular the VIII. Subgroup of the periodic system

These are preferably salts of the noble metals nut organic acids, eg. B. with citric acid, tartaric acid, oxalic acid, salicylic acid, lactic acid, benzoic acid, mucic acid, etc., also halides, cyanides, rhodanides and the like. Verla «W de ^G Ä * Ά * ^ -Leipzig, 1936; also A. H ay! "Handbook of scientific and applied photography", Springer-Verlag, Vienna, 1929 Vol. 3 For the process according to the invention, τ β 'compounds of this type can be used in concentrations of 1 (H to 10 + * g / m ", preferably 1 (H to 10 + ¹ g / m ^a can be stored in layers. When exposed to light, germs arise on which the coloring reactions described below can be carried out.

In addition to the light-sensitive layers just described Kind in which the noble metal compounds themselves are sufficiently photosensitive that the exposed areas, catalytically active noble metal nuclei arise in sufficient quantities, are necessary for the invention Process also suitable layers in which other substances are imagewise upon exposure are changed, in such a way that at the exposed points the or simultaneously present in the layer Noble metal compounds added later are converted into noble metal nuclei, which are then able to are to catalytically decompose peroxides. Layers of this type are known per se. It is about Layers with photoconductive compounds such as zinc oxide, titanium dioxide, bismuth oxide, tin dioxide, lead oxide, Halides, sulfides or selenides of these metal ions, among others. Reference is made to the publication of A. Goetz et al. in Rev. Mod. Physics, 20 (1948), p. 131, and G. M. S c h w a b et al. in Photographic Science, Focal Press London / New York, 1963, p. 342, or to British patent specification 1 043 2 "> 0.

Layers which contain zinc oxide or titanium dioxide in any binders, in particular but hydrophilic binders, e.g. B. silica gel, polyvinyl acetate, partially hydrolyzed polyvinyl acetate, Polyvinyl alcohol, cellulose ester, carboxymethyl cellulose, or natural binders such as gelatin embedded included.

These layers are before or after exposure Precious metal compounds added, which do not have to be photosensitive themselves. At the exposed These noble metal compounds are reduced in places of the layers, so that image-wise noble metal nuclei arise, which in turn can catalytically decompose peroxy compounds.

The inventive method of color development by means of catalytic decomposition of peroxy compounds on noble metals can also be used very well for the amplification of photographic ones Images generated with conventional, especially low-silver, silver halide emulsion layers have been. For this purpose, the emulsion layer is initially exposed after imagewise exposure conventionally developed. The resulting image silver then catalytically causes the decomposition of the Peroxy compound.

The catalytic activity of the surface of the developed image silver can be influenced by the coloring, image-enhancing post-development can be increased by suitable measures.

Such an increase in the catalytic! Activity of the developed image silver is e.g. B. possible through the deposition of traces of catalytically more active noble metals (e.g. Au, Pt, Pd, Ru, Os) on the silver surface, further through a short oxidative s pretreatment of the image silver at higher pH values (pH> 7) z . B. with dissolved or gaseous H ₂ O ₂ , with dissolved perborate, percarbonate persulfate or the like.

A certain increase in the catalytic activity of the developed image silver also already occurs,

ίο if by a short physical development additional silver ions are deposited from the solution phase on the silver surface; by repression of adsorbed, passivating foreign substances (e.g. emulsion stabilizers) is then the Silver surface "cleaned", its catalytic activity increased.

Due to the high reinforcement effect obtained with the catalytic dye formation according to the invention linked by decomposition of the peroxy compound

ao, a considerable increase in relative sensitivity can be achieved. By treating with the Peroxy compound and the subsequent dye formation are visible parts of the image that are visible in normal photographic Processing remain hidden from the eye through development. This results in apparent increases in sensitivity from 5 to 10 ° DIN achieved. You can z. B. a relatively insensitive fine-grained photographic film having a silver halide emulsion layer that is subject to ordinary processing has a sensitivity of 13 ° DIN, expose as if the film had a sensitivity of about 18 ° DIN, without any loss in the image details is noticeable compared to a picture that is out

'the same photographic material was obtained under normal exposure and processing.

In addition, the required image contrast can already be achieved with very low-silver halide layers (0.01 to 0.3 Ag / πι ² ). This not only brings a significant economic advantage; the layers that are low in silver halide also scatter the light less than the conventional, more silver-rich layers; this lower scatter has a very favorable effect on the image sharpness.

For special purposes, the extremely low-silver halide layers can also be used with the fixing or save the bleach-fix process, since the photolytic discoloration of the unusually low-silver Layers in daylight are significantly lower than those of the conventional layers, which are richer in silver.

The method according to the invention can be used both for the intensification of black and white silver images and for the intensification of color photographic images.
The peroxy compounds used for the process according to the invention are inorganic peroxy compounds, e.g. B. perborates, percarbonates or persulfates are suitable. Organic peroxy compounds, for example benzoyl peroxide, can also be used. However, because of its effectiveness and ease of handling in the form of aqueous solutions, hydrogen peroxide is preferably used.

The treatment with the peroxy compound takes place in the presence of reaction components, which are below Oxidation results in compounds that are as deeply colored as possible, so that the previously invisible or barely visible Image is now visible.

The reaction components can be organic compounds that are themselves in

5 6

the oxidation provide the image dye, e.g. B. Amino-, York (1966), p. 382; HLR.Schweizer, »Art-Hydroxy- or aminohydroxy compounds of isolated organic dyes in their intermediate procyclic dyes or heterocyclic aromatics. dukte «, Springer-Verlag Beriin — Göttingen — Hadel-

Examples are: Phenol, Anilin, Brenzberg (1964), p. 295]. Isocyclic and heterocatechol, resorcinol, hydroquinone, o-, m- and p-cyclic hydrazines can also be coupled oxidatively to form dyes with suitable components. for diethyl-phenylenediamine, Ν, Ν-ethylmethyl-phenyl- (example S. Hünig et al., Angew. Chem., 70 U *> S), endiamine, β », m- and p-aminophenol, p-methyl- .S. 215; S. Hünig, Chimia, 15 (1961), b.Ul, una aminophenol, 2,4-diaminophenol- (l), 2,3-dihydroxy Angew. Chem., 74: 818 (1962)]. The coloring naphthalene, 1,6,7-trihydroxynaphthalene, 1,2-diamino- ίο photographic developer substances are naphthalene, 1,8-diaminonaphthalene, benzidine, 2,2'-noble metal nuclei or noble dihydroxybenzidine, diphenylamine, 8 Hydroxychino metal particles are catalytically oxidized by the peroxy compound Un, 5-hydroxyquinoline, 2-hydroxycarbazole, 1-phenylene. Your oxidation products can then pyrazolon- (3) among other things with also present, known photo-

The amino-, hydroxy- or aminohydroxyverbin- 15 graphic color couplers react to form dyes, fertilizers can also be substituted. z. B. With this, all color couplers are suitable, e.g. B. those of the halogen, sulfonic acid, nitro, keto, carboxylic acid, phenol or naphthol series as cyan couplers, the or carbonamide groups. Examples include: indazole series as purple couplers and benzoyl-2,5-dichloro-p-phenylenediamine, l-hydroxy-2-aminoacetanilide series as yellow couplers.
benzene-4-sulfonic acid, l-amino ^ -hydroxy-benzene ^ 20

sulfonic acid, S-amino-S-sulfo-salicylic acid, 1,6,7-tri Example 1

oxy-naphthalene-3-sulfonic acid, benzidine-2,2'-disulfone

acid, benzidine-3,3'-disulfonic acid, 1,8-dihydroxy- A gelatin layer (layer thickness 25 μm) on a

naphthalene-disulfonic acid- (3,6), 4-nitro-catechol. Cellulose triacetate layer adhesive comes in a 0.8% strength

In some cases mixtures of more than one aqueous Na ^ PdiCjOJd solution bathed
After drying and imagewise exposure, such compounds are subject to oxidation during oxidation

much stronger dye formation than the individual components of ultraviolet light will cause the layer to develop for 2 minutes. So z. B. treated a mixture of o-phenyl at 20 ° C with the following developer bath:
endiamine and catechol cause increased dye formation. Even components that alone 30 Solution 1 "
do not give dyes in the event of oxidation, such as B. Tetra

bromohydroquinone or tetrabromo pyrocatechol, 500 ecm of water can be mixed with 5 ecm of glacial acetic acid.

nen when added to other hydroxy, amino or sets. 3 g of 3-amino-

Aminohydroxy compounds cause the dye to form verbenzidine hydrochloride and 2 g of pyrocatechol

strengthen. 35 solved.

In the oxidation of the aromatic amino,
Hydroxy and / or amino hydroxy compounds from solution 2:

are monomeric or polymeric dyes, which _T _ "_ .... , "Xi" * "-" _m o ^ of <it

the quinone imines and azines are related. Some ⁱⁿ _f ⁵⁰ P. "" water, 10 g Nataumacetat

Examples of this oxidative dye formation have been resolved. Then 25 ecm 30 / _o H ₂ O _{2 are written} at HR S he er, »Artificial orga- added.

niche dyes and their intermediates «, Sprin- The two solutions are mixed before use.

ger-Verlag Berlin — Götiingen — Heidelberg (1964), p. Created in the exposed areas of the layer

222, 275, 281 and 293; N. 1. Woroshow, "Basic germs from elementary layers during the exposure to the synthesis of intermediate products and coloring 45 palladium, which in the development of the hydrogen", Akademie-Verlag Berlin (1966), p. 703 to fabric peroxide of solution 2 catalytically decompose. The 789; A. Schaeffer, "Chemistry of dyestuffs and phenols of solution 1 are thereby dated imagewise for their application" (Technical progress reports, a diffusion-resistant brown-black dyestuff oxy-Vol. 60), Theodor Steinkopff-Verlag Dresden-Leipzig.
(1963), p. 59ff. 50 After the development, the layer is watered

In addition to dye precursors, and are of course also dried.
Leuco dye compounds and vat dyes ver. · Ι τ

reversible, which can be oxidized to dyes. b e 1 s ρ 1 e l Z

For examples, see H. R. Schweizer, »Art- A transparent layer carrier made of cellulose tri-

Liche organic dyes and intermediates «, 55 acetate is coated with a solution which is 400 ecm Springer-Verlag Berlin-Göttingen — Heidelberg (1964), water 6 ml of a 10% aqueous solution of p. 250 and 320. Polyvinyl alcohol and 2 g TiO ₂ with a particle size

For the method according to the invention are uueh of 0.3 and 0.4 μπι and 0.1 mg of erythrosine as speksolche Contains oxidizable organic compounds suitable sensitizer. Then it is genetically which only dries up in a subsequent reaction with others.

bonds result in the cheap dye. In principle processing

all reaction systems are usable, which under oxy-

dative coupling lead to dyes. The dried layer is referred to in a usual

be in particular on the so-called color sensitometer behind a gray step wedge exposed photographic developer of phenylenediamine 65 and then for 10 minutes with a 1% or aminopyrazolone series [cf. treated for example CEK aqueous NaAuCl ₄ solution. Then M ees and TH J ames, "The Theory of the photon is 2 minutes, treated New following solutions at 20 ⁰ C in a bath of the graphic Process", 3rd Edition, MacMillan Co.:

7 8

Solution 1: The two solutions are mixed before use.

5 g of 3-carbamyl-4- are added to 500 ecm of water. Finally, the layer is watered and dried.

aminopyrazolone- (5), 20 g NaH ₂ PO ₄ · H ₂ O dissolved. "el. Treatment with the last-mentioned bath

can be done in daylight. The contrast of the original

Solution 2: The initial silver image is

In 500ccm of water, 1OgNa ₂ HPO ₄ - 12H ₂ O windings are greatly increased. This also makes the

and 0.5 g of Na ₂ P ₂ O- dissolved and a sensitivity of the material apparently increased by 50 ecm, since

30% aqueous hydrogen peroxide solution either has more image details than with the same exposure

give. ^and then conventional photographic

ίο processing become visible or there with equally good

Solution 3: final image quality the more light sensitive

10 g Na ₂ HPO ₄ and 10 g l-naphthol-2-sulfone material only much shorter (factor 10 to 100)

acids are dissolved in 500 ecm of water and need to be exposed to light than is the case with subsequent

Addition of aqueous sodium hydroxide to a conventional processing would be required.

pH adjusted to 8.5. * 5 Instead of the sodium percarbonate intermediate

act that increases the catalytic activity of the

The three solutions are increased before using wrapped silver, ζ can. B. also an intermediate mixing, treatment with 2% perborate _{solution, with 1% The developed material is 1/2 minute long PdCl 2} solution, with 1% PtCl ₂ solution or with watered and dried. A blue-violet 20 1% strength AuCl ₃ solution is obtained. Also a short latin negative picture of the original. Exposure to gaseous H ₂ O ₂ (especially a similarly good result is obtained when the mixture is mixed with gaseous NH ₃ ) increases the catalyzed layer with a 1% aqueous silver activity of the image silver, nitrate solution instead of the Na [ AuCl ,,] solution treated
will. 25 Example 4

10 ml of a possible haze-free silver halide

A silver bromide iodide gel gelatin emulsion that is as free of fog as possible is converted to 250 ecm 5% gelatin

tine emulsion layer (4.5 mole percent Ag) is applied to the solution. 50 ml are united in this solution

a support made of polyalkylene terephthalate in 10% strength aqueous solution of the color coupler pour. Layer thickness about 10 μ.

After imagewise exposure (0.5 seconds with OH X-rays between fluorescence intensifier films) the layer is first ^{treated for 5 minutes at _m_NH_r H 20 0} C in the following developer: 35 _; ^ ie «37

3.5 g p-methylaminophenol
9.0 g hydroquinone

60.0 g Na ₂ SO ₃ sice. SO ₃ H

40.0 g Na ₂ CO _{3 40}

stirred into 1 1 H _{2 O.} The mixture becomes about 20 \

Then, after a short intermediate watering, a thick layer is poured. Silver application about 0.05 bi

Fixed for 5 minutes with the bath at the following rate of 0.2 g / m ² .

Composition: After drying, the layer is applied imagewise (e.g., R

45 in a standard sensitometer) for 1 second

250 g ^Na ^ | O ₃ · 5 H ₂ U, _{exposed to a gray} step wedge and then exposed for 2 minutes

20 g _{NaHSO3 long} färb _in a conventional manner in the following Bad

in 1 1 H ₂ O. developed:

After another brief wash, 2.8 g Ν, Ν-diethyl p-phenylenediamine sulfate,

the layer is coated with a solution for 5 minutes. 50 ₂ , 0 g Na ₂ SO ₃ sicc.,

acts, which 2.0 g of ethylenediaminetetraacetic acid sodium,

25 g sodium percarbonate and 2.0 g KBr,

200 ecm 30% H ₂ O ₂ I -2 g hydroxylamine sulfate,

_{55 on} ff £ g

contains. The catalytic activity of the surface of the *

Developed silver is thereby increased. A very weak, negative, blue-green is obtained

Then the image is in the following nes, image-silver-containing dye image for 2 minutes. Bath treated: Then the layer is m

60 of a solution treated which

Solution: * * i * -, t-ua ²⁰ S sodium perborate and

In 500 ecm of water, 2 g of 1,6,7-Tnhydroxy- _{m can} ^ y * _{H o}

naphthalene-3-sulfonic acid and 2.5 g of 1,2-diamino _on jj O _H

benzene hydrochloride dissolved. ²

65 contains the catalytic activity of the image film

Solution 2: this increases the area

100 g of sodium acetate are dissolved in 500 ecm of water. Then the layer lasts for another 5 minutes

dissolved and 25 ecm of 30% H ₂ O _x added. treated in the following bath:

Solution 1:

15 g of phenylhydrazine-2-sulfonic acid sodium will be dissolved in 500 ecm 0.1% acetic acid.

Solution 2:

7 g of sodium perborate and 40 g of sodium acetate are dissolved in 500 ecm of water. Then 50 ecm of 30% H ₂ O _{2 are} added.

The two solutions are mixed before use.

The dye image is considerably enhanced by this post-treatment.

Finally it is watered and dried.

Since the layer contains extremely little halogen silver, no fixation is required.

H c i s ρ i e 1 5

A multilayered material with color imaging with a red-sensitive silver halide emulsion layer containing a color coupler for the production of the ao blue-green partial image, a green-sensitive silver halide emulsion layer with a purple coupler and a blue-sensitive silver halide emulsion

ίο

layer with a yellow coupler is exposed imagewise behind a gray step wedge with an amount of light, which is about a tenth of the amount of light required with conventional processing. Subsequently is color developed for 8 minutes in a conventional manner in the color developer of Example 4.

The layer is then treated three times in succession, alternately for 1 minute, with a 2.5% strength sodium percarbonate solution and the color developer solution specified above. This alternating bath post-treatment enhances the original color image.
After a short intermediate wash and bleach fixation in the following bath:

Solution 1:

50 g Na ₂ S ₁ O ₃ in 500 ecm H ₂ O,

Solution 2:

25 g of K ₃ [Fe (CN) ₆ ] in 500 ecm of H ₂ O

(both solutions mixed before use),
the layer is watered out and dried.

Claims (4)

1 2 with regard to sensitivity and image sharpness are depending on patent claims: but this method, which has been tried and tested for a long time, has its limits, so that there has been no lack of new attempts 1. To develop processes for the production of photographic processes which use both physical and chemical principles, photographic processes are also known If necessary with the subsequent application of one in which a semiconductor layer is exposed imagewise Noble metal salt solution from noble metals of the I. and and in the exposed areas noble metal nuclei ab-VIII. Subgroups of the periodic system are decided, which are then used to produce an image standing germs in an image-wise distribution io produced from this noble metal, in particular silver, or one of them and in which the metal seed image with reac dye image are used. The material used for this vertion component for a color-supplying oxide process has a considerable getion reaction to a visible image, and it is less sensitive to light than the conventional one characterized in that materials having a silver halide emulsion layer. the metal nucleation is catalytically involved in the nuclei 15 The consumption of silver salts for the production of the decomposable peroxy compounds in the presence of a silver image or a dye mixture produced by color photographic development of one or more reaction components for winding is also high a coloring oxidation reaction treated as in conventional photographic processes, will. without any other advantages being achieved. There 2. The method according to claim 1, characterized in the consumption of relatively expensive noble metals by light-sensitive layers which are light-sensitive, especially silver salts, in which conventional compounds of silver, gold, nellen photographic processes and the last Metals of the platinum group or such light-sensitive processes are relatively high, both detectable substances are contained which do not adhere to these noble metal compounds at the points of operation that are disadvantageous for economic reasons. to decompose ter formation of noble metal nuclei The invention is based on the object of process assets. for the production or amplification of photographic 3. Process for enhancing photographic images with the greatest possible savings Pictures, characterized in that silver pictures of noble metal, in particular silver salts, are wrapped in 30 containing catalytically decomposable peroxy compounds, which in a simple and economical manner Presence of reaction components for the production or reinforcement of monochrome or coloring oxidation reaction are treated. allow multicolor photographic images. 4. The method according to claim 3, characterized in that a process for the production of photos has now been drawn in that the catalytic activity of the image-graphic images is found in which a light-sensitive record is exposed to a light-sensitive record before the color-giving one by image silver surface compared to the peroxy compound , catalytic oxidizing material, optionally under the following reaction through the deposition of Ag, Au application of a precious metal salt solution made from precious metal and / or noble metals of the VIII. subgroup of the tall of the I. or VIII. subgroup existing Periodic table or by treatment with germs in an image-wise distribution and Oxidizing agents is increased. 40 in which the metal nucleation with reaction components