Silver halide light sensitive color photographic material and process for preparing color proof

A silver halide light sensitive color photographic material is disclosed, comprising a reflective support having on one side of the support a hydrophilic colloid layer containing a white pigment and one or more silver halide emulsion layers, wherein at least one of the silver halide emulsion layers contains a silver halide emulsion having a spectral sensitivity maximum at a wavelength of 730 nm or more, and an average primary particle size of the white pigment being 0.30 .mu.m or more.

FIELD OF THE INVENTION 
The present invention relates a silver halide light sensitive color 
photographic material suitable for preparing a proofing color image (a 
color proof) from images obtained by color separation and halftone dot 
image conversion, in color lithographic printing, and a process for 
preparing a color proof making use of the photographic material. 
BACKGROUND OF THE INVENTION 
In the process of color lithographic printing, as method for preparing a 
color proof from plural sheets of black-and-white halftone dot images 
obtained by color separation and halftone dot image conversion, the 
overlay method and the surprint method are conventionally known, which are 
methods of forming color images by the use of a photopolymer or a diazo 
compound. 
The overlay method is advantageous in that it is very simple, HAS a low 
production cost and can be used only by overlaying four-color (subtractive 
primaries and black) film sheets. However, it is disadvantageous in that 
the overlaying of the film sheets causes a gloss, which gives a texture 
different from that of the print. 
The surprint method is a method in which colored images are superposed on 
the same support. This method is known to include methods in which the 
colored images are obtained by toner development that utilize adhesive 
properties of a photopolymerizable material, as disclosed in U. S. Pat. 
Nos. 3,582,327, 3,607,264, and 3,620,726. 
Another method is known in which transfer is made on a support by the use 
of a light sensitive coloring sheet, followed by exposure and development 
to form an image, and thereafter another coloring sheet is superposed 
thereon, followed by repetition of the same process to prepare a color 
proof, as disclosed in JP-B 47-27441 (herein, the term, JP-B means 
examined and published Japanese Patent) and JP-A 56-501217 (herein, the 
term, JP-A means unexamined and published Japanese Patent Application). 
Still another method is known in which, using light sensitive coloring 
sheets, corresponding color separation films are exposed and developed, 
and the resulting respective colored images are transferred and formed on 
the same support, as disclosed in JP-A 59-97140. As toners and as 
colorants for the coloring sheets, used to form these images, the same 
coloring materials as used in printing inks can be used. Because of this 
advantage, the resulting color proof displays a color tone resembling that 
of the print. 
In these methods, however, images must be superposed and transferred in the 
process of preparing a color proof, and there are disadvantages that 
operation thereof takes a relatively long time and they result in a high 
production cost. As methods that have eliminated such disadvantages, a 
method of preparing a color proof by the use of a silver halide color 
photographic material provided on a white support is disclosed in JP-A 
56-113139, 56-104335, 62-280746, 62-280747, 62-280748, 62-280749, 
62-280750 and 62-280849. In the method, plural sheets of color-separated 
black-and-white halftone dot images, converted into halftone dot images 
which are color-separated from a color original, are successively 
photographically printed on a sheet of color photographic paper by contact 
printing or the like, followed by color development, and a color image 
formed of dyes imagewise produced from couplers upon the color development 
is used as a color proof. However, this technique has a problem that 
varying the dot percentage to make a color image resemble a print results 
in an unwanted density increase in the white background of the image, 
leading to unacceptable coloring of the background. This technique further 
has the disadvantage that an attempt to make a color image resemble the 
print results in an insufficiency in the density of black images such as 
text compared to that of the print and, on the other hand, any means taken 
to increase this density so as to make a black image such as text have a 
density resembling that of a print brings about a low resemblance of the 
print to the color image, making it difficult to satisfy both at the same 
time. 
JP-A 1-260629, 61-233732 and 4-1632 disclose a silver halide color 
photographic material having four emulsion layers comprised of Y, M, C and 
Black layers which are different in spectral sensitivity from each other. 
However, there is described no method for solving the above problems with 
respect to the density increase of the white background when varying the 
dot percentage to resemble the print. JP-A 8-304960 discloses a silver 
halide photographic material containing a pigment having an average 
primary particle size of 0.25 .mu.m or more. However, nothing is described 
therein, with respect to the density increase of the white background when 
varying the dot percentage to resemble the print. It is further described 
that the average primary particle size is preferably within the range of 
0.26 to 0.30 .mu.m and only titanium oxide having an average primary 
particle size of at most 0.28 .mu.m is exemplified. 
SUMMARY OF THE INVENTION 
Accordingly, it is an object of the present invention to provide a silver 
halide color photographic material for use in color proofing whereby when 
a color proof is prepared using the photographic material from halftone 
dot image information obtained by color separation and halftone dot image 
conversion, a stable image can be obtained without producing a density 
increase in the white background even when varying the dot percentage to 
resemble a print, and to provide a process for preparing a color proof. 
The above object of the present invention can be achieved by the following 
constitution: 
(1) a silver halide light sensitive color photographic material comprising 
a reflective support comprising a base paper provided on each side thereof 
with a polyolefin resin coat layer having on one side of the support a 
hydrophilic colloid layer containing a white pigment and one or more 
silver halide emulsion layers, characterized in that at least one of the 
silver halide emulsion layers comprises a silver halide emulsion having a 
spectral sensitivity maximum at a wavelength of 730 rim or more, and an 
average primary particle size of the white pigment being 0.30 .mu.m or 
more; 
(2) the silver halide light sensitive color photographic material 
comprising a reflective support comprising a base paper provided on each 
side thereof with a polyolefin resin coat layer having on one side of the 
support a hydrophilic colloidal layer containing a white pigment and one 
or more silver halide emulsion layers described in above (1), wherein a 
reflection density of the photographic material is 1.0 or more at a 
wavelength of the spectral sensitivity maximum of the silver halide 
emulsion contained in at least one of the silver halide emulsion layers; 
(3) the silver halide light sensitive color photographic material 
comprising a reflective support comprising a base paper provided on each 
side thereof with a polyolefin resin coat layer having on one side of the 
support a hydrophilic colloidal layer containing a white pigment and one 
or more silver halide emulsion layers described in (1) or (2), wherein the 
silver halide photographic material comprises a silver halide emulsion 
used for forming a yellow image, a silver halide emulsion used for forming 
a magenta image, a silver halide emulsion used for forming a cyan image 
and a silver halide emulsion used for forming a black image; 
(4) the silver halide light sensitive color photographic material 
comprising a reflective support comprising a base paper provided on each 
side thereof with a polyolefin resin coat layer having on one side of the 
support a hydrophilic colloidal layer containing a white pigment and one 
or more silver halide emulsion layers described in any one of above (1) to 
(3), wherein at least one of the silver halide emulsion layers comprises a 
compound represented by the following formulas [I] to [IV]: 
##STR1## 
wherein R.sub.1 represents a hydrogen atom or a substituent, R.sub.2 
represents a substituent, m represents the number of the substituent 
R.sub.2 (i.e., m is preferably 0 or an integer of 1 to 3), provided that 
when m is 0, R.sub.1 is an electron-withdrawing group having a Hammett's 
substituent constant .sigma.p of 0.20 or more and when m is 1, or 2 or 
more, at least one of R.sub.1 and R.sub.2 is an electron-withdrawing group 
having a Hammett's substituent constant .sigma.p of 0.20 or more, Z.sub.1 
represents a non-metallic atom group necessary for forming a 
nitrogen-containing 5-membered heterocyclic ring; 
R.sub.3 represents a hydrogen atom or a substituent; Z.sub.2 represents a 
non-metallic atom group necessary for forming a nitrogen-containing 
6-membered heterocyclic ring with --NH-- through condensing with the 
pyrazole ring; 
R.sub.4 and R.sub.5 each represent an electron-withdrawing group having a 
Hammett's substituent constant .sigma.p of 0.20 or more, provided that a 
sum of ap values of R.sub.4 and R.sub.5 is 0.65 or more, and Z.sub.3 
represents a non-metallic atom group necessary for forming a 
nitrogen-containing 5-membered heterocyclic ring; 
R.sub.6 and R.sub.7 each represent a hydrogen atom or a substituent, 
Z.sub.4 represents a non-metallic atom group necessary for forming a 
nitrogen-containing 6-membered heterocyclic ring; and 
X.sub.1, X.sub.2, X.sub.3 and X.sub.4 each represent a hydrogen atom or a 
group capable of being released upon coupling reaction with an oxidation 
product of a color developing agent; and 
(5) a process for preparing a color proof by a process comprising 
subjecting a silver halide light sensitive color photographic material to 
exposure based on color-separated yellow image information, magenta image 
information, cyan image information and black image information and 
further subjecting to processing to form an yellow image component, a 
magenta image component, a cyan image component and a black image 
component, wherein the silver halide color photographic material is the 
one described in any one of (1) to (4) described above. 
DETAILED DESCRIPTION OF THE INVENTION 
Examples of white pigments used in the present invention include rutile 
type titanium dioxide, anatase type titanium dioxide, barium sulfate, 
barium stearate, silica, alumina, zirconium oxide, and kaolin. Of these, 
titanium dioxide is preferred for various reasons. The white pigment is 
preferably dispersed in a water soluble binder of hydrophilic colloid such 
as gelatin into which the processing solution is permeable. The coating 
amount of the white pigment is preferably 0.1 to 50 g/m.sup.2, and more 
preferably 0.2 to 10 g/m.sup.2. The average primary particle size of the 
white pigment is preferably 0.30 to 3.0 .mu.m, more preferably 0.32 to 2.0 
.mu.m, and still more preferably 0.32 to 1.0 .mu.m. The average primary 
particle size is referred to as a cubic root of a particle volume 
corresponding to the maximum value of the product of the particle volume 
and its frequency, when particles of the white pigment are observed with 
an electron microscope. The white pigment can be used singly or in the 
form of a mixture of plural and different kinds of white pigments. In 
cases where plural white pigments different in average particle size are 
used, the average primary particle size of the mixture shall preferably be 
0.30 .mu.m or more, and the average particle size of any one of white 
pigments before being mixed may be 0.30 .mu.m or more. 
A hydrophilic colloid layer containing the white pigment relating to the 
invention is preferably provided between a support and a silver halide 
emulsion layer nearest to the support. Between the support and the silver 
halide emulsion layer nearest to the support, a light insensitive 
hydrophilic colloid layer other than the white pigment containing layer 
can optionally be provided, including a sublayer coated on the support and 
an interlayer provided at an arbitrary position. The hydrophilic colloid 
layer containing the white pigment preferably further contains a light 
absorbing material capable of preventing halation due to the support or 
white pigment, in terms of enhancement of sharpness. The white pigment can 
be contained separately from the layer containing colloidal silver, a 
water soluble dyestuff or its solid particle dispersion, which is 
advantageous in terms of sensitivity. 
The silver halide color photographic material according to the invention 
preferably comprises inclusion of a silver halide emulsion having a 
spectral sensitivity maximum at a wavelength of 730 nm or more. The silver 
halide emulsion having a spectral sensitivity maximum at a wavelength of 
730 nm or more can be obtained by selectively employing sensitizing dye(s) 
known in the art. The silver halide emulsion having a sensitivity maximum 
at a wavelength of 730 nm or more is preferably included in a silver 
halide emulsion layer nearest to the support. The color photographic 
material according to the invention comprises one or more silver halide 
emulsion layers. Among the silver halide emulsion layers, the emulsion 
layer containing the silver halide emulsion having a sensitivity maximum 
at a wavelength of 730 nm or more is preferably provided closest to the 
support. 
The silver halide color photographic material according to the invention 
preferably comprises at least a yellow image forming silver halide 
emulsion layer, a magenta image forming silver halide emulsion layer and a 
cyan image forming silver halide emulsion layer. Silver halide emulsions 
contained in these emulsion layers each have a spectral sensitivity 
maximum at different wavelengths from each other. Each of the wavelengths 
of the spectral sensitivity maximum is preferably separated from the other 
by 20 nm or more. 
The color photographic material according to the invention, which has not 
been processed, preferably has a reflection density of at least one of the 
wavelengths of spectral sensitivity maximum of the silver halide 
emulsion(s) contained in the silver halide emulsion layer(s). The 
reflection density, i.e., the reflection density at the emulsion side of 
the photographic material can be measured by any of several methods known 
in the art. For example, there can be used a spectral reflection density 
value obtained by measuring reflectiondensities at the emulsion side of 
the photographic material using Color Analyzer 607 available from Hitachi 
Seisakusho. A means for making the reflection density 1.0 or more is 
preferably incorporation of a water soluble dyestuff having absorption 
within the spectral sensitivity range of the silver halide emulsion and/or 
to provide an antihalation in the lowest layer or another layer. Further, 
the dyestuff is preferably incorporated in the form of a solid particle 
dispersion to prevent the dyestuff from diffusing within the photographic 
material. 
Examples of the water soluble dyestuff usable in the present invention 
include those of oxonol, cyanine, merocyanine, azo, anthraquinone, and 
allylidene. Of these, an oxonol dyestuff and merocyanine dyestuff are 
preferred in terms of high degradability on processing and having no 
sensitizing ability to silver halide. The oxonol dyestuff is described in 
U.S. Pat. No. 4,187,225; and JP-A 48-42826, 49-5125, 49-99620, 50-91627, 
51-77327, 55-120660, 58-24139, 58-143342, 59-38742, 59-111640, 59-111641, 
59-168438, 60-218641, 62-31916, 62-66275, 62-66276, 62-185755, 62-273527 
and 63-139949. The merocyanine dyestuff is described in JP-A 50-145124, 
58-120245, 63-34537, 63-34538, 63-34539, and 63-58437. 
Exemplary examples of the oxonol dyestuff and merocyanine dyestuff include 
water soluble yellow dyestuffs AIY-1 to AIY-14, water soluble magenta 
dyestuffs AIM-1 to AIM-14 and water soluble cyan dyestuffs AIC-1 to 
AIC-14, as described in Japanese Patent Application No. 7-150291. 
Exemplary examples of water soluble dyestuffs other than the oxonol 
dyestuff and merocyanine dyestuff include water soluble yellow dyestuffs 
AIY-15 to AIY-18, water soluble magenta dyestuffs AIM-15 to AIM-18 and 
water soluble cyan dyestuffs AIC-15 to AIC-18, as described in Japanese 
Patent Application No. 7-150291. Furthermore, the water soluble dyestuff 
usable in the invention include dyestuffs A-1 to A-43 described in JP-A 
4-330437. The water soluble dyestuff is incorporated in an amount giving 
1.0 or more of the reflection density, which is measured at the wavelength 
of the spectral sensitivity maximum of the emulsion included in the 
unprocessed photographic material. The water soluble dyestuff can be 
incorporated singly or in combinations thereof. 
The antihalation layer can be provided in the lowest layer or any other 
layer. The antihalation layer contains a light-absorbing compound. The 
light-absorbing compound includes a variety of light-absorbing organic 
compounds and inorganic compounds. Suitable inorganic compounds include 
colloidal silver and colloidal manganese, of which colloidal silver is 
specifically preferred. These colloid-formed metals are superior in 
decolorizability and advatageously employed in the color photographic 
material according to the invention. The colloidal silver, e.g., black 
colloidal silver can be obtained by a process in which silver nitrate is 
reduced, in gelatin, in the presence of a reducing agent such as 
hydroquinone, phenidone, ascorbic acid, pyrogallol or dextrin, while being 
maintained at specific alkalinity, followed by being neutralized, cooled, 
set and subjected to noodle washing to remove the reducing agent and 
unnecessary soluble salts. When reduced in alkalinity in the presence of 
an azaindene compound or a mercapto compound to prepare colloidal silver 
particles, a colloidal silver dispersion comprised of homogeneous 
particles can be obtained. The coverage of the colloidal silver can 
optionally be selected so as to give 1.0 or more of the reflection density 
measured at 730 nm of the unprocessed photographic material. In cases 
where is used in combination with other water soluble dyestuff(s), the 
reflection density of the unprocessed photographic material is preferably 
to be 1.0 or more. 
The color photographic material according to the invention can contain a 
dyestuff having at least one of a carboxy group, sufonamido group and 
sulfamoyl group in the form of a solid particle dispersion, in a silver 
halide emulsion layer and/or other hydrophilic colloid layer. 
Examples of the dyestuff having at least one of a carboxy group, sufonamido 
group and sulfamoyl group include exemplified dyestuffs 1-1 to 8-7 
described in Japanese Patent Application No. 7-150291. The dyestuff having 
at -Least one of a carboxy group, sufonamido group and sulfamoyl group is 
substantially insoluble in water (i.e., water at a pH of 7 or less), 
having a hydrophilic group which is capable of being dissociated at a pH 
of 9 or more. The dyestuff, which is made to be present in gelatin or a 
polymeric binder, in the form of a fine solid particle dispersion (i.e., 
solid particles having microscopic dimension and preferably an average 
particle size of 10 .mu.m or less, and more preferably 1 .mu.m or less) 
obtained by means of a technique of pulverizing with a ball mill or a sand 
mill or a technique of dissolving in an organic solvent and dispersing in 
a gelatin solution, can be incorporated into any one of photographic 
component layers including a light sensitive emulsion layer and a 
hydrophilic colloid layer. The fine solid particle dispersion of the 
dyestuff having at least one of a carboxy group, sufonamido group and 
sulfamoyl group can be stably present, in a water-insoluble form, in the 
color photographic material, and almost disappears by being subjected, 
after exposure, to processing with a color developing solution (preferably 
at a pH of 9 or more). The dyestuff having at least one of a carboxy 
group, sufonamido group and sulfamoyl group may be used in combination 
thereof or in combination with a water soluble dyestuff or colloidal 
silver. The dyestuff having at least one of a carboxy group, sufonamido 
group and sulfamoyl group can be incorporated by appropriately selecting 
the content so as to give 1.0 or more of a reflection density measured at 
a wavelength of the spectral sensitivity maximum of at least one of the 
emulsions included in the unprocessed color photographic material 
according to the invention. In cases where incorporated in combination 
with another water soluble dyestuff, the reflection density of the 
unprocessed photographic material is to be 1.0 or more. The amount to be 
incorporated is generally in the range of 0.001 to 0.5 g/m.sup.2. 
In one preferred embodiment of the present invention, the silver halide 
color photographic material comprises inclusion of a yellow image forming 
silver halide emulsion layer, a magenta image forming silver halide 
emulsion layer and a cyan image forming silver halide emulsion layer. In 
another preferred embodiment of the invention, the silver halide color 
photographic material further includes a black image forming silver halide 
emulsion layer, in addition to the yellow image forming silver halide 
emulsion layer, magenta image forming silver halide emulsion layer and 
cyan image forming silver halide emulsion layer. The black image forming 
silver halide emulsion may be one which can singly form a black image. 
Alternatively, the black image forming silver halide emulsion may be one 
which is designed so as to give a neutral, black image with a sufficient 
density through exposure and development of a black image forming silver 
halide emulsion, in addition to an image formed upon development of at 
least a part of the yellow image forming silver halide emulsion, magenta 
image forming silver halide emulsion and cyan image forming silver halide 
emulsion. In one preferred embodiment thereof, the yellow image forming 
layer contains a yellow image forming silver halide emulsion, the magenta 
image forming layer containing a magenta image forming silver halide 
emulsion, the cyan image forming layer containing a cyan image forming 
silver halide emulsion, and the black image forming layer containing a 
black image forming silver halide emulsion. In this case, as a silver 
halide emulsion contained in each image forming layer are employed four 
kinds of silver halide emulsions which are different in the wavelength at 
the spectral sensitivity maximum from each other. The spectral sensitivity 
of each emulsion can be arbitrarily selected. A preferred combination is 
comprised of a blue-sensitive emulsion, a green-sensitive emulsion, a 
red-sensitive emulsion and infrared-sensitive emulsion. Another preferred 
combination is comprised of a green-sensitive emulsion, a red-sensitive 
emulsion, an infrared-sensitive emulsion 1 and an infrared-sensitive 
emulsion 2 (which is different in its wavelength of the spectral 
sensitivity maximum from the infrared-sensitive emulsion 1). However, 
embodiments of the invention are not limited to these. 
Combinations of the wavelength of the spectral sensitivity maximum of the 
emulsion with an image forming layer is optional, and preferred examples 
thereof include the following combinations. Thus, when the term, Y-Em, 
M-Em, C-Em and K-Em represent a yellow image forming emulsion, a magenta 
image forming emulsion, a cyan image forming emulsion and a black image 
forming emulsion, respectively, and the trm, B-Em, G-Em, R-Em and IR-Em 
represent a blue-sensitive emulsion, a green-sensitive emulsion, a 
red-sensitive emulsion and an infrared-sensitive emulsion, respectively; 
each of the image forming layers can be formed by the combination of these 
emulsions, as shown below. 
______________________________________ 
No. B-Em G-Em R-Em IR-Em 
______________________________________ 
1 Y-Em M-Em C-Em K-Em 
2 Y-Em M-Em K-Em C-Em 
3 Y-Em C-Em M-Em K-Em 
4 Y-Em C-Em K-Em M-Em 
5 Y-Em K-Em M-Em C-Em 
6 Y-Em K-Em C-Em M-Em 
7 M-Em C-Em K-Em Y-Em 
8 M-Em C-Em Y-Em K-Em 
9 M-Em K-Em Y-Em C-Em 
10 M-Em K-Em C-Em Y-Em 
11 M-Em Y-Em C-Em K-Em 
12 M-Em Y-Em K-Em C-Em 
13 C-Em K-Em Y-Em M-Em 
14 C-Em K-Em M-Em Y-Em 
15 C-Em Y-Em M-Em K-Em 
16 C-Em Y-Em K-Em M-Em 
17 C-Em M-Em Y-Em K-Em 
18 C-Em M-Em K-Em Y-Em 
19 K-Em Y-Em M-Em C-Em 
20 K-Em Y-Em C-Em M-Em 
21 K-Em M-Em Y-Em C-Em 
22 K-Em M-Em C-Em Y-Em 
23 K-Em C-Em Y-Em M-Em 
24 K-Em C-Em M-Em Y-Em 
______________________________________ 
In No. 1 described above, for example, combinations of each of 
blue-sensitive, green-sensitive, red-sensitive and infrared-sensitive 
emulsions with yellow, mgenta, cyan and black image forming layers, 
respectively, form a blue-sensitive yellow image forming layer, a 
green-sensitive magenta image forming layer, a red-sensitive cyan image 
forming layer and a infrared-sensitive black image forming layer. 
In the above combinations, blue-sensitive, green-sensitive, red-sensitive 
and infrared-sensitive emulsions are employed. In addition thereto, the 
use of an emulsion having a spectral sensitivity maximum other than the 
above can be combined with the image forming layer. For example, the 
above-described combination can be replaced by another combination of four 
emulsion which are different in their spectral sensitivity maximum 
wavelength, such as a combination of a green-sensitive, red-sensitive, 
infrared-sensitive (1) and infrared-sensitive (2) emulsions. 
The black image forming emulsion is preferably combined with the black 
image forming layer. Alternatively, the black image forming emulsion is 
allowed to be contained in plural image forming layers to form a black 
image upon exposure and development. In one embodiment, a black image 
forming emulsion is allowed to be contained in a cyan image forming layer 
and a red image forming layer, followed by black-imagewise exposure and 
development to concurrently form cyan and red images, leading to black 
image formation. In this case, a cyan image forming emulsion can be 
contained concurrently in the cyan image forming layer, i.e., a cyan 
coupler can be used both for cyan image formation and for black image 
formation. In the red image forming layer are preferably contained a 
yellow coupler and a magenta coupler. In another embodiment, a black image 
forming emulsion is allowed to be contained in a magenta image forming 
layer and a green image forming layer, followed by black-imagewise 
exposure and development to concurrently form magenta and green images, 
leading to black image formation. In this case, a magenta image forming 
emulsion can be contained concurrently in the magenta image forming layer, 
i.e., a magenta coupler can be used both for magenta image formation and 
for black image formation. In the green image forming layer are preferably 
contained a yellow coupler and a cyan coupler. In still another 
embodiment, a black image forming emulsion is allowed to be contained in a 
yellow image forming layer and a blue image forming layer, followed by 
black-imagewise exposure and development to concurrently form yellow and 
blue images, leading to black image formation. In this case, a yellow 
image forming emulsion can be contained concurrently in the yellow image 
forming layer, i.e., a yellow coupler can be used both for yellow image 
formation and for black image formation. In the blue image forming layer 
are preferably contained a magenta coupler and a cyan coupler. 
A preferred method for allowing the black image forming emulsion to be 
contained in plural image forming layers is shown below. In layer 
constitution No. 10 described above, for example, some examples of layer 
arrangement are shown below. 
______________________________________ 
Image Forming Layer Emulsion contained 
______________________________________ 
Magenta image forming layer 
B-Em 
Red image forming layer G-Em 
Cyan image forming layer R-Em + G-Em 
Yellow image forming layer IR-Em 
Magenta image forming layer B-Em + G-Em 
Green image forming layer G-Em 
Cyan image forming layer R-Em 
Yellow image forming layer IR-Em 
Magenta image forming layer B-Em 
Blue image forming layer G-Em 
Cyan image forming layer R-Em 
Yellow image forming layer IR-Em + G-Em 
Magenta image forming layer 1 B-Em 
Magenta image forming layer 2 G-Em 
Cyan image forming layer R-Em + G-Em 
Yellow image forming layer IR-Em + G-Em 
Magenta image forming layer B-Em + G-Em 
Cyan image forming layer 1 G-Em 
Cyan image forming layer 2 R-Em 
yellow image forming layer IR-Em + G-Em 
Magenta image forming layer B-Em + G-Em 
Yellow image forming layer 1 G-Em 
Cyan image forming layer R-Em + G-Em 
Yellow image forming layer 2 IR-Em 
Magenta image forming layer B-Em + G-Em 
Cyan image forming layer R-Em + G-Em 
Yellow image forming layer IR-Em + G-Em 
______________________________________ 
In the layer constitution other than Layer Constitution No. 10 described 
above, similarly, the black image forming emulsion can concurrently be 
contained in plural image forming layers to obtain a black image. 
Combinations of emulsions having other spectral sensitivity maximum 
wavelengths can be similarly constituted. The coating order of emulsion 
layers from the side nearest to the support can be rather arbitrary 
selected. Each emulsion layer, e.g., the magenta image forming layer may 
be formed of a single layer or plural layers. 
The silver halide emulsion relating to the invention can be spectrally 
sensitized with a spectral-sensitizing dye selected from dyes known in the 
art. 
Cyan couplers usable in the invention are preferably a polycyclic 
hetero-ring compounds formed by condensing with a nitrogen atom contained 
in a pyrrole ring or pyrazole ring. Of these, the cyan couplers are 
represented by formulas [I] to [IV] afore-mentioned. 
In formula [I], R.sub.1 represents a hydrogen atom or a substituent, 
R.sub.2 represents a substituent, m represents the number of the 
substituent R.sub.2 (i.e., m is preferably 0 or an integer of 1 to 3), 
provided that when m is 0, R.sub.1 is an electron-withdrawing group having 
a Hammett's substituent constant .sigma.p of 0.20 or more and when m is 1, 
or 2 or more, at least one of R.sub.1 and R.sub.2 is an 
electron-withdrawing group having a Hammett's substituent constant 
.sigma.p of 0.20 or more. Examples of the electron-with drawing group 
having a Hammett's substituent constant .sigma.p of 0.20 or more include 
sulfonyl, sulfinyl, sulfonyloxy, sulfamoyl, phospholyl, carbamoyl, acyl, 
acyloxy, oxycarbonyl, carboxyl, cyano, nitro, halogenated alkoxy, 
halogenated aryloxy, pyrrolyl and tetrazolyl groups an a halogen atom. 
Examples of the sulfonyl group include alkyl sulfonyl, arylsulfonyl, 
halogenated alkylsulfonyl and halogenated arylsulfonyl groups; examples of 
the sulfinyl group include alkylsulfinyl and arylsulfinyl groups; examples 
of the sulfonyloxy group include alkylsulfonyloxy and arylsulfonyloxy 
groups; examples of the sulfamoyl group include N,N-dialkylsulfamoyl, 
N,N-diarylsulfamoyl, and N-alkyl-N-arylsulfamoyl groups; examples of the 
phosphoryl group include alkoxyphosphoryl, aryloxyphosphoryl and 
arylphosphryl groups; examples of the carbamoyl group include 
N,N-dialkylcarbamoyl, N,N-diarylcarbamoyl, and N-alkyl-N-arylcarbamoyl 
groups; examples of the acyl group include alkylcarbonyl and arylcarbonyl 
groups; examples of the acyloxy group include an alkylcarbonyloxy group; 
and examples of the oxycarbonyl group include alkoxycarbonyl and 
aryloxycarbonyl groups. An example of the halogenated alkoxy group 
includes .alpha.-halogenoalkoxy; and examples of the halogenated aryloxy 
group include tetrafluoroaryloxy and pentafluoroaryloxy groups. Examples 
of the pyrrolyl and tetrazolyl groups include 1-pyrrolyl and 1-tetrazolyl 
groups, respectively. In addition to the above groups, trifluoromethyl, 
heptafluoro-i-propyl, nonylfluoro-t-butyl groups and tetrafluoroaryl and 
pentafluoroaryl groups aree also preferred. 
As a substituent represented by R.sub.1 and R.sub.2, other than the 
electron-withdrawing groups described above, various groups are cited and 
they are not specifically lomited. Representative examples thereof include 
alkyl, aryl, anilino, acylamino, sulfonamido, alkylthio, arylthio, 
alkenyl, cycloalkyl, cycloalkenyl, alkynyl, heterocyclic, alkoxy, aryloxy, 
hetrocyclic-oxy, siloxy, amino, alkylamino, imido,ureido, sulfamoylamino, 
alkoxycarbonylamino, aryloxycarbonylamino, alkoxycarbonyl, 
aryloxycarbonyl, heterocyclic-thio, thioureido, hydroxy and mercapto 
groups, spiro-compound residue and bridged hydrocarbon compound residue. 
The alkyl group preferably has 1 to 32 carbon atoms, which may be stretch 
chained or brnched. The aryl group is preferablt a phenyl group. Examples 
of the acylamino group include alkylcarbonylamino and arylcarbonylamino 
groups; and examples of the sulfonamido group include alkylsulfonylamino 
and arylsulfonylamino groups. Alkyl and aryl components of the alkylthio 
and arylthio groups include the alkyl group and aryl group described 
above. The alkenyl group preferably has 2 to 32 carbon atoms, and the 
cycloalkyl group preferably has 3 to 12 carbon atoms, and more preferably 
5 to 7 carbon atoms. The alkenyl group may be stretch-chained or brached. 
The cycloalkenyl group preferably has 3 to 12 carbon atoms, and more 
preferably 5 to 7 carbon atoms. Examples of the ureido group include alkyl 
ureido and arylureido groups; examples of the the sulfamoylamino group 
include alkylsulfamoylamino and arylsulfamoylamino groups; the 
hetrerocyclic group is preferably the one having 5 to 7 carbon atoms, and 
examples thereof include 2-furyl, 2-thienyl, 2-pyrimidinyl and 
2-benzothiazolyl; the heterocyclic-oxy group is preferably 5- to 
7-membered ring, and examples thereof include 
3,4,5,6-tetrahydropyranyl-2-oxy and 1-phenyltetrazole-5-oxy; examples of 
the siloxy group include trimethylsiloxy, triethylsiloxy and 
dimethylbutylsiloxy; and examples of the imido group include 
3-heptadecylsucciimido, phthalimido and glutarimido groups. The spiro 
compound residue includes spiro[3.3]heptane-1-yl; and examples of the 
bridged hydrocarbon compound residue include bicyclo[2.2.1]heptane-1-yl, 
tricyclo[3.1.1.sup.3.7 ]decane-1-yl and 
7,7-dimethyl-bicyclo[2.2.1]heptane-1-yl. Z.sub.1 represents a non-metallic 
atom group necessary for forming a nitrogen-containing 5-membered 
heterocyclic ring; 
R.sub.3 represents a hydrogen atom or a substituent; Z.sub.2 represents a 
non-metallic atom group necessary for forming a nitrogen-containing 
6-membered heterocyclic ring with --NH-- through condensing with the 
pyrazole ring; 
R.sub.4 and R.sub.5 each represent an electron-withdrawing group having a 
Hammett's substituent constant .sigma.p of 0.20 or more, provided that a 
sum of up values of R.sub.4 and R.sub.5 is 0.65 or more, and Z.sub.3 
represents a non-metallic atom group necessary for forming a 
nitrogen-containing 5-membered heterocyclic ring; 
R.sub.6 and R.sub.7 each represent a hydrogen atom or a substituent, 
Z.sub.4 represents a non-metallic atom group necessary for forming a 
nitrogen-containing 6-membered heterocyclic ring; and 
X.sub.1, X.sub.2, X.sub.3 and X.sub.4 each represent a hydrogen atom or a 
group capable of being released upon coupling reaction with an oxidation 
product of a color developing agent. 
Exemplary examples of the cyan couplers represented by formulas [I] to [IV] 
include Compounds C-1 to C-44 described in Japanese Patent Application No. 
6-47243, and compound C-45, as shown below. 
##STR2## 
The silver halide color photographic material according to the invention 
preferably contains, in its component layer, a brightening compound, in 
the form of a solid particle dispersion. 
The brightening compound is preferably substantially water-insoluble 
compound exhibiting brightening effect. Any type of a compound, which is 
substantially water-insoluble and exhibits brightening effect at ordinary 
temperatures, can employed. Herein, the expression "substantially 
water-insoluble" means solubility at 25.degree. C. being 1.0 g or less per 
100 g of water. As the substantially water-insoluble, brightening 
compound, a water-insoluble brightening agent conventionally known cab be 
employed. Specifically, a substantially water-insoluble organic salt 
represented by the following formula [V] can be preferably employed, and a 
substantially water-insoluble organic salt represented by the following 
formula [VI] can be further preferably employed. 
EQU A.multidot.[B]n Formula [V] 
wherein A represents a brightening agent moiety containing an anionic group 
such as carboxyl group; B represents a cation having total carbon atoms of 
15 or more, such as ammonium or pyridium; and n is an integer of 1 to 9. 
Preferred examples of the brightening agent moiety containing an anionic 
group include a substituted stilbene type brightening agent, substituted 
coumarin type brightening agent and substituted thiophene type brightening 
agent. 
EQU C.multidot.[D]n Formula [VI] 
wherein C represents a brightening agent moiety containing a sulfonic acid 
group; D represents a cation having total carbon atoms of 15 or more, such 
as ammonium or pyridinium; and n is an integer of 1 to 9. Preferred 
examples of the brightening agent moiety containing a sulfonic acid group 
include a sulfonic acid group-containing, substituted stilbene type 
brightening agent, substituted coumarin type brightening agent and 
substituted thiophene type brightening agent. 
The brightening agent moiety represented by "A" of the formula [V] or "B" 
of the formula [VI] can be readily synthesized by reference to, e.g., 
"Keikozohakuzai" (Brightening Agent) edited by Kaseihin Kogyokai; British 
patent No. 920,988; German Patent No. 1,065,838; and U.S. Pat. No. 
2,610,152. The compound represented by formula [V] or [VI] can be readily 
synthesized by mixing the brightening corresponding to the A of formula 
[V] or the C of formula [VI] with an organic cation having total carbon 
atoms of 15 or more, such as ammonium or pyridium and corresponding to the 
B of formula [V] or the D of formula [VI}. The organic cation is 
preferably an ammonium ion having 15 or more carbon atoms in total. 
Example of the substantially water-insoluble brightening compound 
preferably used in the invention are shown below, but the compound is not 
limited to these examples. 
##STR3## 
The brightening compound can be incorporated, in the form of fine solid 
particles, into the silver halide color photographic material. The fine 
solid particles is added in the form of a solid particle dispersing 
solution. The fine solid particles of the brightening compound can be 
dispersed by a method of pulverizing the compound and dispersing in water 
or a hydrophilic colloid aqueous solution such as a gelatin solution by 
the use of high-speed stirring type dispersing machine; a method of 
dispersing in water or a hydrophilic colloid aqueous solution such as a 
gelatin solution by the use of a dispersing machine having a high shearing 
stress, such as Manton-Gaulin homogenizer; and a dispersing method using a 
ultrasonic homogenizer. An anionic surfactant, nonionic surfactant or 
betaine type surfactant can be preferably used in dispersing. The fine 
solid particle dispersion has an average particle size of 0.05 to 5 .mu.m, 
and preferably 0.1 to 2 .mu.m. The brightening compound is incorporated 
preferably into a light-insensitive hydrophilic colloid layer, and more 
preferably into a light-insensitive hydrophilic colloid layer provided 
between a support and a silver halide emulsion layer nearest to the 
support. The brightening compound is incorporated preferably in an amount 
of 0.01 to 2 g/m.sup.2, and more preferably 0.05 to 1 g/m.sup.2. 
In the process of subjecting the silver halide color photographic material 
to exposure, based on halftone dot information comprised of 
color-separated yellow image information, magenta image information, cyan 
image information and black image information, to prepare a color proof, 
the halftone dot image information, at least a part of which is converted 
to halftone dot images having 200.times.10.sup.3 or more dots (preferably, 
300.times.10.sup.3 or more dots, more preferably 400.times.10.sup.3 or 
more dots, and still more preferably 400.times.10.sup.3 to 
2000.times.10.sup.3 or more dots) per inch.sup.2 at a 40-dot percentage, 
is employed. The dot number can be measured by counting the photographed 
dot image by using a common microscope. 
The halftone dot image used in the invention is specifically effective in 
the case of a halftone dot image used for high definition printing by a 
conventional AM screening method. In addition, the present invention is 
further more effective in the case of a dot image formed by a screening 
method referred to as a so-called FM screen method in which the frequency 
is modulated. Namely, if a color proof is prepared from the halftone dot 
image information which is prepared by means of frequency modulation and 
by means of a method other than the present invention, the average 
distance between dots is maintained to be a distance larger than a certain 
distance when the percentage of the original is small. However, with an 
increase of the dot percentage, the average distance between dots is 
progressively reduced in the case of the frequency modulation compared to 
AM modulation. Accordingly, fluctuation of the neutrality of the dot 
percentage of the proof prepared based on the dot percentage of the 
original is easily produced, due to minute slippage of resister marks, 
which is a standard for processing and registration. 
In the present invention, it is preferred that the halftone dot image 
information is a halftone image recorded on a film and that exposure is 
carried out by bringing the film into close contact with the photographic 
material and then by scanning the photographic material. To achieve close 
contact, a vacuum contacting method is preferably employed. Further, it is 
preferred to carry out exposure to light from the light source through an 
optical means to improve parallelism. Means for improving the parallelism 
of light emitted from the light source include an optical lens, a 
reflecting mirror or a honeycomb structure in which light other than 
parallel light is absorbed by walls due to the light passing through a 
linear tube-type optical path. In addition, parallelism can be enhanced by 
means of aggregated optical fibers. Furthermore, it is also preferred to 
carry out exposure by means of laser scanning, based on the halftone dot 
image information described above. 
Next, a reflective support used in the present invention will be explained. 
It is preferable that the reflective support used in the present invention 
has a base paper, as base, laminated on both sides thereof with a 
polyolefin resin. The raw material of the base paper used for the present 
invention can be selected from those ordinarily used for photographic 
paper. For example, natural pulp, synthetic pulp, mixtures of natural pulp 
and synthetic pulp and various raw materials for papering are cited. 
Ordinarily, conifer pulp, hard-wood pulp and natural pulp wherein a mixed 
pulp of a conifer pulp and a hard-wood pulp are the main components are 
widely be used. In addition, in the above-described support, additives 
ordinarily used in papers such as sizing agents, fixing agents, heavy duty 
strengthening agents, fillers, anti-static agents and dyes may be added. 
In addition, surface sizing agents, surface tension agents and anti-static 
agents may be coated appropriately on the surfaces. 
For the support described above, those having a flat surface and ordinarily 
a weight of 50 through 300 g/m.sup.2, are preferably used. A resin, 
laminated on both surfaces may be selected from a single polymer such as 
ethylene, polyethylene terephthalate and .alpha.-olefines such as 
polypropylene, a copolymer of at least two kinds of the above-mentioned 
olefines and mixtures of at least two kinds of polymers. Specifically 
preferable polyolefin resins are a low density polyethylene, high density 
polyethylene or an admixture of them. 
The molecular weight of the polyolefin resin is not specifically limited. 
However, normally, those within a range of 20,000 through 200,000 are 
preferable. 
A polyolefin resin-laminated layer on one side of a photographic support 
used in the present invention, where a photographic emulsion is coated, is 
preferably 5 through 50 .mu.m and more preferably 7 through 35 .mu.m. 
With regard to polyolefin used for laminating the rear side (the side 
opposite to the surface wherein emulsion layers are provided) of the 
support, ordinarily, a mixture of a low density polyethylene and a high 
density polyethylene is fused and then laminated. This layer is generally 
subjected to a matting treatment. 
In a polyolefine resin used for laminating the surface (on which emulsion 
layers are provided) of the support used in the present invention, 
preferably 13 through 20 weight % and more preferably 15 through 20 weight 
% of white pigment is dispersed and mixed. 
As a white pigment, an inorganic and/or an organic white pigment can be 
used, including sulfate of alkaline earth metals such as barium sulfate, 
carbonate of alkaline earth metals such as calcium carbonate, silica such 
as fine powdery silicic acid and synthetic silicate, calcium silicate, 
alumina, alumina hydrate, titanium oxide, zinc oxide, talc and clay. 
Of these, preferable are barium sulfate, calcium carbonate and titanium 
oxide. More preferable are barium sulfate and titanium oxide. 
The titanium oxide may either be a rutile type or an anatase type. In 
addition, those laminated with a metal oxide such as alumina oxide hydrate 
and ferrite oxide hydrate may also be used. 
In addition, it is preferable to use an anti-oxidation agent, a colored 
pigment for improving whiteness and a fluorescent brightening agent. When 
laminating the surface and a back side of the support, in order to enhance 
flatness of an exposed photographic paper in a normal environment, a means 
to increase the density of the resin layer on the surface slightly more 
than the back side and a means to increase the amount of lamination of the 
back side to be greater than the surface, are ordinarily adopted. 
In addition, for ordinary lamination of the surface and back of the 
support, a polyolefin resin component is formed on the support by means of 
a fusion extruding coating method. It addition, it is preferable that the 
surface of the support and, if necessary, both sides of the support are 
subjected to corona discharge processing as well as flame processing. In 
addition, it is also preferable to provide a sub-coating layer for 
improving adhesion property with the photographic emulsion on the surface 
of the surface lamination layer or to provide a backing layer for 
improving printing and writing property and anti-static property on the 
lamination layer on the back side. 
It is preferable that sharpness is improved by coating a hydrophilic 
colloidal layer containing a white pigment on the support. As a white 
pigment, the same white pigment as the foregoing can be used. Titanium 
oxide is preferable. In a hydrophilic colloidal layer containing a white 
pigment, it is preferable to add a hollow fine particle polymer and a high 
boiling organic solvent since sharpness and/or curling resistance can be 
improved. 
In a preferable embodiment of the present invention, it is preferable to 
form a protective layer on the outermost surface of the photographic 
material and to add fine particle powder into the protective layer. As the 
fine particle powder (matting agent) and using method thereof, it is 
preferable to use a technology described in Japanese Patent O.P.I. 
Publication No. 95283/1994, page 4 left column, line 42nd through page 4, 
right column, line 33. In addition, as a reflective support used in the 
present invention, synthetic resin film supports such as polypropylene 
laminated with polyolefin on the surface can also be used. 
There is no limit to the thickness of the reflective support used in the 
present invention, 80 through 160 .mu.m being preferable, and 90 through 
130 .mu.m being more preferable. 
The surface of the reflective support used in the present invention may be 
flat or may have some appropriate surface coarseness. However, it is 
preferable to select a reflective support having glossiness close to a 
printed material. For example, it is preferable to use a white support 
whose average surface roughness stipulated in JIS B 0601-1976 is 0.30 
through 3.0 .mu.m. 
In the present invention, surface roughness on an image forming surface is 
preferably 0.30 through 3.0 .mu.m. For this purpose, a matting agent may 
be added in a structural layer on the image forming surface side. The 
matting agent may be added in the silver halide emulsion layer, the 
protective layer, the intermediate layer and the subbing layer. It may be 
added to plural layers, and preferably, to the outermost light-sensitive 
layer. 
It is preferable that the surface on the image forming layer side of the 
photographic material of the present invention has glossiness close to a 
printed material. For example, the degree of glossiness GS (60.degree.) 
measured by a method stipulated in JIS-Z8741 is preferably 5 through 15, 
and more preferably 5 through 20. 
As the silver halide emulsion used in the present invention there may be 
used a surface latent image-type silver halide emulsion that is imagewise 
exposed to form a latent image on a surface, and further processed to 
thereby form a negative image. There may also be suitably used an internal 
latent image-type silver halide emulsion having its grain surface 
previously unfogged which, after being imagewise exposed, is subjected to 
fogging treatment (nucleus-formation treatment) followed by surface 
development or which, after being imagewise exposed, is subjected to 
surface development while being subjected to fogging treatment to thereby 
obtain a direct positive image. 
The above fogging treatment may be achieved by overall exposure of the 
emulsion to light, chemically fogged with a fogging agent, processed in a 
strong developing solution or subjected to heat treatment. The 
aforementioned internal latent image-type silver halide grain-containing 
emulsion is an emulsion containing silver halide crystal grains each 
having a sensitivity speck mainly in the interior to form an internal 
latent image when exposed to light. 
The previously unfogged internal latent image-type silver halide emulsion 
usable in the present invention is an emulsion containing silver halide 
grains each forming a latent image mainly within the grain and having most 
of sensitivity specks in the interior, and comprised of silver bromide, 
silver chloride, silver chlorobromide, silver chloroiodide, silver 
iodobromide, or silver chloroiodobromide. 
The above emulsion is most preferably one which when coated on a support to 
prepare a sample so that its silver coating weight is in the range of 
about 1 to 3.5 g/m.sup.2, and when a portion of the prepared sample is 
subjected to light intensity scale exposure for specified periods of time 
ranging from 0.1 to 1.0 second and developed at 20.degree. C. for 4 
minutes in the following surface developing solution A, which contains 
substantially no silver halide solvent for developing the surface image of 
the grain, the maximum density of the thus processed piece is not more 
than 1/5 of the maximum density of the other part of the same sample that 
was obtained by being similarly exposed and developed at 20.degree. C. for 
4 minutes in the following internal developing solution B capable of 
developing the internal latent image. 
______________________________________ 
(Surface developing solution A) 
Metol 2.5 g 
L-ascorbic acid 10.0 g 
Sodium metaborate, tetrahydrate 35.0 g 
Potassium bromide 1.0 g 
Water to make 1000 cc 
(Internal developing solution B) 
Metol 2.0 g 
Anhydrous sodium sulfite 90.0 g 
Hydroquinone 8.0 g 
Sodium carbonate, monohydrate 52.5 g 
Potassium bromide 5.0 g 
Potassium iodide 0.5 g 
Water to make 1000 cc 
______________________________________ 
The internal latent image-type silver halide emulsions suitably usable in 
the present invention include those prepared in various methods, such as 
the conversion-type silver halide emulsion described in U.S. Pat. No. 
2,592,250; the silver halide emulsion comprising internal chemically 
sensitized silver halide grains described in U.S. Pat. Nos. 3,206,316, 
3,317,322 and 3,367,778; the emulsion containing polyvalent metallic 
ion-occluded silver halide grains described in U.S. Pat. Nos. 3,271,157, 
3,447,927; the silver halide emulsion comprising weakly chemically 
sensitized silver halide grains containing a dopant described in U.S. Pat. 
No. 3,761,276; the silver halide emulsion comprising grains having a 
multilayer structure described in JP-A Nos. 50-8524, 50-38525 and 53-2408; 
and the silver halide emulsion described in JP-A Nos. 52-156614 and 
55-127549. 
The internal latent image-type silver halide grain usable in the present 
invention may be any of silver halides such as silver bromide, silver 
chloride, silver chlorobromide, silver chloroiodide, silver iodobromide or 
silver chloroiodobromide. Silver chloride containing grains are superior 
in the developability and are suitable for rapid processing. 
The silver halide crystal grains used in the present invention may have any 
of several common forms such as a cubic form, an octahedral form, a 
tetradecahedral form comprised of (100) and (111) faces, a form having 
(110) faces, a spherical form or a tabular form. Preferred silver halide 
grains are those having an average grain diameter of 0.05 to 3 .mu.m. The 
silver halide emulsion used in the present invention may be either a 
monodisperse emulsion comprised of grains which are homogeneous in the 
grain diameter and crystal habit, or a polydisperse emulsion comprised of 
grains which are inhomogeneous in the grain diameter and crystal habit. In 
the present invention, the monodisperse silver halide emulsion is one in 
which silver halide grains having a grain diameter within the range of the 
average diameter rm.+-.20% accounts for preferably not less than 60%, more 
preferably not less than 70%, and still more preferably not less than 80% 
of the weight of the total silver halide grains. The average grain 
diameter (rm) herein is defined as the grain diameter ri in the instance 
where the product of frequency ni of the grain having a grain diameter ri 
and ri.sup.3, i.e., ni.times.ri.sup.3, comes to the maximum (rounded to 
three decimal places). Herein, the grain diameter, in the case of a 
spherical silver halide grain, is the diameter itself, while in the case 
of a non-spherical grain, is the diameter of an equivalent circule to the 
grain projected area. The grain diameter can be obtained by a method in 
which the grain is electron microphotographically enlarged 10,000 to 
50,000times, and the diameter of the enlarged grain image on its photo 
print or the area of the projection grain image enlarged likewise is 
actually measured. (The number of grains for measurement shall be 1000 or 
more at random.) 
The most preferred highly monodispersed emulsion is comprised of silver 
halide grains having a grain diameter distribution width of not more than 
20%, the distribution width being defined by 
EQU grain diameter standard deviation/average diameter.times.100=distribution 
width (%) 
wherein the above average grain diameter and the grain diameter standard 
deviation are to be found from the earlier defined ri. 
The monodisperse emulsion can be obtained by adding an aqueous silver salt 
solution and an aqueous halide solution under controlled pAg and pH 
conditions according to a double-jet precipitation method. For 
determination of the addition rate, reference can be made to JP-A Nos. 
54-48521 and 58-49938. To obtain a high monodisperse emulsion, there can 
be used the method for growing the grain in the presence of a 
tetrazaindene compound, which was disclosed in JP-A No. 60-122935. 
In addition, it is also preferable to add two or more kinds of 
mono-dispersed emulsions in one sensitive layer. 
The grain size in each emulsion layer of the photographic material of the 
present invention can be determined from a wide range, considering various 
properties including performance thereof, specifically, its sensitivity, 
sensitivity balance, color separation sharpness and graininess. 
In the photographic material of the present invention, it is preferable to 
contain a nitrogen-containing heterocyclic compound having a mercapto 
group. The preferable compounds are those represented by Formula [XI] 
described in JP-A No. 6-95283, page 19, right column, line 20th through 
49th. The more preferable compounds are those represented by Formula 
[XII], Formula [XIII] and [XIV] described in the above-mentioned 
specification, page 20, left column, line 5th through page 20, right 
column, line 2nd. Exemplary examples of the compounds include Compounds 
(1) through (39) described in JP-A No. 64-73338, page 11 through page 15. 
The addition amount of the above-mentioned mercapto compound may optionally 
be varied depending of the kind of compounds used and the added layer. 
Ordinarily, when added to the silver halide emulsion layer, it is 
preferable to be 10.sup.-8 through 10.sup.-2 mol and more preferable to be 
10.sup.-6 through 10.sup.-3 mol. 
In one preferable embodiment of the present invention, the grain size of 
silver halide is preferably 0.1 through 0.6 .mu.m for the red-sensitive 
layer emulsion, 0.15 .mu.m through 0.8 .mu.m for the green-sensitive layer 
emulsion and 0.3 through 1.2 .mu.m for the blue-sensitive layer emulsion. 
Preferred magenta couplers used in the present invention are compounds 
represented by [M-1] described in JP-A No. 95283/1994, page 7, right 
column in terms of superior spectral absorption properties of coloring 
dyes. Practical example of preferable compounds include compounds M-1 
through M-19 described in the above-mentioned specification, page 8 
through page 11. In addition, as other examples, compounds M-1 through 
M-61 described in European Patent No. 0,273,712, pp. 6 through 21 and 
compounds 1 through 223 described in European Patent No. 0,235,913, pp. 36 
through 92, except those described above. The above-mentioned couplers may 
be used in combination with other kinds of magenta couplers. Ordinarily, 
they can be used preferably in a range of 1.times.10.sup.-3 through 1 mol 
and more preferably in a range of 1.times.10.sup.-2 through 
8.times.10.sup.-1 mol per mol of silver halide. 
In the photographic material of the present invention, spectral absorption 
.lambda..sub.L0.2 of the magenta image is preferably 580 through 635 nm. 
In the photographic materials whose .lambda..sub.L0.2 is 580 through 635 
nm, .lambda.max of the spectral absorption of the magenta image is 
preferably 530 through 560 nm. 
Here, .lambda..sub.L0.2 and .lambda.max of the spectral absorption of the 
magenta image of the photographic material of the present invention are 
measured by the following methods. 
(Measurement method of .lambda..sub.L0.2 and .lambda.max) 
In the case of a positive type, the photographic material of the present 
invention is uniformly exposed to red light in a minimum amount capable of 
obtaining the minimum density of the cyan image and is also uniformly 
exposed to blue light a minimum amount capable of obtaining the minimum 
density of the yellow image. Following this, a white light is irradiated 
through an ND filter, and then, when the photographic material is 
subjected to photographic processing, an integrating sphere is mounted to 
a spectrophotometer and the value is corrected to zero by means of a 
standard white plate made of magnesium oxide. A magenta image is prepared 
by adjusting the density of the ND filter in such a manner that the 
maximum value of absorbance when spectral absorption of 500 through 700 nm 
is measured. 
In the case of the negative type, a photographic material is exposed to a 
green light through the ND filter. When the photographic material is 
subjected to photographic processing to form a magenta image, the density 
of the ND filter is adjusted to the same maximum absorbance as the 
above-mentioned positive type. .lambda..sub.L0.2 s defined as a wave 
longer than a wavelength wherein the maximum absorbance shows 1.0 in the 
spectral absorbance curve and its absorbance shows 0.2. 
In order to adjust spectral absorption property of the magenta dye image 
(or a cyan and a yellow image) as described above, it is preferable to add 
a compound having a color tone adjusting effect. Preferred examples of 
such compounds include compounds represented by [HBS-I] and [HBS-II] 
described in JP-A No. 6-95283, page 22 are preferable, and compounds 
represented by Formula [HBS-II] described in the above-mentioned 
specification, page 22. 
It is preferable that a yellow coupler be contained, in addition to a 
magenta coupler, in the magenta image forming layer of the photographic 
material of the present invention. The difference of pKa of the 
above-mentioned couplers is preferably within 2 and more preferably within 
1.5. The preferable yellow coupler contained in the magenta image forming 
layer of the present invention is a coupler represented by Formula [Y-Ia] 
described in JP-A 6-95283, page 12, right column. Of the couplers 
represented by the above-mentioned specification, the more preferable ones 
are those having a pKa value which is not lower than that of a coupler 
represented by a combined coupler [M-1] by 3, when it is combined with a 
magenta coupler represented by [M-1]. 
Practical examples of preferable compounds include, in addition to 
compounds Y-1 and Y-2 described in JP-A No. 6-95283, compounds (Y-1) 
through (Y-58) described in JP-A No. 139542/1990, pp. 13 through 17, but 
the compounds are not limited these compounds. 
As a cyan coupler contained in the cyan image forming layer according to 
the present invention, conventional types such as phenol, naphthol or 
imidazole couplers can be used. Typically, phenol type couplers which are 
each substituted by an alkyl group, an acylamino group or a ureido group, 
naphthol type couplers formed from a 5-aminonaphthol nucleus and a 
two-equivalent type couplers having an oxygen atom-introduced leaving 
group. Of these, preferable compounds include those represented by Formula 
[C-I] and [C-II] described in JP-A No. 95283/1994, page 13. As a yellow 
dye forming coupler, a conventional acylacetoanilide type coupler can 
preferably be used. Of these, a benzoylacetoanilide type and a 
pivaloylacetoanilide type are advantageously employed. In the present 
invention, .lambda..sub.L0.2 of the yellow image is preferably 515 nm or 
less. The .lambda..sub.L0.2 of the present invention is defined by JP-A 
No. 6-95283, page 21, right column line 1 through 24. It refers to the 
size of unnecessary absorption at longer wavelength side in the spectral 
absorption property of the yellow dye image. In the present invention, the 
spectral absorption of the yellow image is preferably .lambda..sub.L0.8 of 
not less than 450 nm, and more preferably .lambda..sub.L0.8 of not less 
than 455 nm. In addition, .lambda..sub.L0.2 is preferably 510 or less. 
.lambda.max is preferably 430 or more. 
In the present invention, an integrating sphere is mounted on a 
spectrophotometer HITACHI 320 to measure spectral absorbance. 
When the photographic material of the present invention employs a coupler 
to form a yellow image, any of several couplers can be employed provided 
that they satisfy the above-mentioned conditions. Examples of preferable 
couplers include those represented by Formula [Y-1] described in JP-A No. 
6-95283, page 21. Practical examples of the above-mentioned couplers are 
preferably compounds described in JP-A No. 3-241345, pp. 5 through 9 and 
compounds represented by Y-I-1 through Y-I-55. In addition, compounds 
described in JP-A No. 3-209466, pp. 11 through 14 and compounds 
represented by Y-1 through Y-30 are also preferably used. 
The above-mentioned yellow couplers are preferably 1.times.10.sup.-3 
through 1 mol, and more preferably 1.times.10.sup.-2 through 
8.times.10.sup.-1 mol per mol of silver halide in the silver halide 
emulsion layer. 
The couplers used in the present invention are respectively preferably 
1.times.10.sup.-3 through 1 mol, and more preferably 1.times.10.sup.-2 
through 8.times.10.sup.-1 mol per mol of silver halide in the silver 
halide emulsion layer. When an oil-in-water type-emulsifying dispersion 
method is employed for adding couplers and other organic compounds used 
for the photographic material of the present invention, in a 
water-insoluble high boiling organic solvent, whose boiling point is 
150.degree. C. or more, a low boiling and/or a water-soluble organic 
solvent are combined if necessary and dissolved. In a hydrophilic binder 
such as an aqueous gelatin solution, the above-mentioned solutions are 
emulsified and dispersed by the use of a surfactant. As a dispersing 
means, a stirrer, a homogenizer, a colloidal mill, a flow jet mixer and a 
supersonic dispersing machine may be used. 
After dispersion, or concurrently with dispersion, a step to remove a low 
boiling organic solvent may be introduced. Preferred examples of the high 
boiling organic solvent capable of being used for dissolving a coupler for 
dispersion include phthalic acid esters such as dioctylphthalate, 
diisodecylphthalate and dibutylphthalate, phosphoric acid ester such as 
tricresyl phosphate and trioctylphosphate and phosphine oxides such as 
trioctyl phosphine oxide. The dielectric constant of the high boiling 
organic solvent is preferably 3.5 to 7. In addition, two or more kinds of 
the high boiling organic solvent may be used in combination. 
As a high boiling organic solvent, the specifically preferable compounds 
are those represented by [HBS-I] and [HBS-II] described in JP-A No. 
6-95283, page 22, and more specifically preferable compounds are those 
represented by [HBS-II]. Practical compounds are compounds I-1 through 
II-95 described in JP-A No. 2-124568, page 53 through 68. 
As a surfactant used for adjusting surface tension when dispersing or 
coating photographic additives, the preferable compounds are those 
containing a hydrophobic group having 8 through 30 carbon atoms and a 
sulfonic acid group or its salts in a molecule. Exemplary examples thereof 
include A-1 through A-11 described in JP-A No. 64-26854. In addition, 
surfactants, in which a fluorine atom is substituted to an alkyl group, 
are also preferably used. The dispersion is conventionally added to a 
coating solution containing a silver halide emulsion. The elapsed time 
from dispersion until addition to the coating solution and the time from 
addition to the coating solution until coating are preferably short. They 
are respectively preferably within 10 hours, more preferably within 3 
hours and still more preferably within 20 minutes. 
To each of the above-mentioned couplers, to prevent color fading of the 
formed dye image due to light, heat and humidity, an anti-fading agent may 
be added singly or in combination. The preferable compounds or a magenta 
dye are phenyl ether type compounds represented by Formulas I and II in 
JP-A No. 2-66541, phenol type compounds represented by Formula IIIB 
described in JP-A No. 3-174150, amine type compounds represented by 
Formula A described in JP-A No. 64-90445 and metallic complexes 
represented by Formulas XII, XIII, XIV and XV described in JP-A No. 
62-182741. The preferable compounds to form a yellow dye and a cyan dye 
are compounds represented by Formula I' described in JP-A No. 1-196049 and 
compounds represented by Formula II described in JP-A No. 5-11417. 
It is preferable that a compound reacting with the oxidation product of a 
color developing agent be incorporated into a layer located between 
light-sensitive layers for preventing color staining and that the compound 
is added to the silver halide emulsion layer to decrease fogging. As a 
compound for such purposes, hydroquinone derivatives are preferable, and 
dialkylhydroquinone such as 2,5-di-t-octyl hydroquinone are more 
preferable. The specifically preferred compound is a compound represented 
by Formula II described in JP-A No. 4-133056, and compounds II-1 through 
II-14 described in the above-mentioned specification pp. 13 through 14 and 
compound 1 described on page 17. 
In the photographic material according to the present invention, it is 
preferable that static fogging is prevented and light-durability of the 
dye image is improved by adding a UV absorber. The preferable UV absorber 
is benzotriazoles. The specifically preferable compounds are those 
represented by Formula III-3 in JP-A No. 1-250944, those represented by 
Formula III described in JP-A No. 64-66646, UV-IL through UV-27L described 
in JP-A No. 63-187240, those represented by Formula I described in JP-A 
No. 4-1633 and those represented by Formulas (I) and (II) described in 
JP-A No. 5-165144. 
It is also to incorporate an oil-soluble dye or a pigment to improve white 
background. Preferred examples of the oil-soluble dye are compounds 1 
through 27 described in JP-A No 2-842, page 8 to 9. In the photographic 
material of the present invention, gelatin is preferably used as a binder. 
Specifically, gelatin, extraction solution of which is subjected to 
hydrogen peroxide treatment to remove colored components of gelatin; 
ossein gelatins which are extracted from hydrogen peroxide-treated raw 
material ossein or manufactured from uncolored raw bone, are preferably 
used to enhance transmittance. 
Gelatin used for the present invention may be any of an alkaline-processed 
ossein gelatin, an acid-processed gelatin, gelatin derivatives and 
modified gelatins. Specifically, the alkaline-processed ossein gelatin is 
preferable. The transmittance of the gelatin used in the photographic 
material relating to the present invention is preferably 70% or more, when 
a 10% solution is prepared and its transmittance at 420 nm is measured by 
the use of a spectrophotometer. 
The jelly strength of the gelatin used in the present invention (measured 
by means of a PAGI method) is preferably 250 or more, and more preferably 
270 g or more. 
The total weight of gelatin contained on the image forming side of the 
photographic material according to the present invention is preferably 
less than 11 g/m.sup.2. With regard to a lower limit, there is no specific 
limit. However, 3.0 g/m.sup.2 or more is preferable in terms of 
photographic performance. The amount of gelatin is calculated in 
conversion to the weight of gelatin having moisture content of 11.0% when 
measured through a moisture measurement method described in the PAGI 
method. 
As a hardener for the binders, a vinylsulfone type hardener and a 
chlorotriazine type hardener are preferably used independently or two or 
more of them are used in combination. Compounds described in JP-A Nos. 
61-249054 and 61-245153 are preferably employed. It is also preferable to 
add antiseptics and anti-mildew agents described in JP-A No. 3-157646 in a 
colloidal layer to prevent propagation of mildew and bacteria which 
adversely affect photographic performance and image storage stability. 
The yellow image forming layer, the magenta image forming layer and the 
cyan image forming layer relating to the present invention are coated on a 
support with an arbitrary order of coating from the support. One 
preferable embodiment is that, from the support, are the cyan image 
forming layer, the magenta image forming layer and the yellow image 
forming layer. In addition, if necessary, a black image forming layer, an 
intermediate layer, a filter layer and a protective layer may also be 
provided. 
In the photographic material of the present invention, the reflection 
density of a unprocessed sample at the wavelength of the spectral 
sensitivity maximum of the cyan image forming silver halide emulsion layer 
is preferably 0.7 or more. 
The photographic material of the present invention is obtained by 
incorporating a colorant material such as a dye having absorption at the 
above-mentioned wavelengths and black colloidal silver in any of 
photographic structural layers of the present invention. In the 
photographic material of the present invention, a water-soluble dye may be 
added to an arbitrary silver halide emulsion layer and/or other 
hydrophilic colloid photographic structural layer. In addition, in the 
photographic material of the present invention, a dye having at least one 
of a carboxyl group, a sulfonamide group and a sulfamoyl group may be 
incorporated by solid-dispersion in an arbitrary silver halide emulsion 
layer and/or other hydrophilic colloid photographic structural layer. 
Examples of the dye having at least one of a carboxyl group, a sulfonamide 
group and a sulfamoyl group include compounds represented by Formulas [I] 
through [IX] described in JP-A No. 6-95283, pp. 14 through 16. 
Examples of the dyes represented by the above-mentioned Formula [I} through 
{VIII} include compounds I-1 through VIII-7 described in JP-A No. 4-18545 
are cited, but is not limited to these. 
There is also specifically no limit to a layer to which the above-mentioned 
dyes and colloidal silver are incorporated. However, it is preferable that 
they be incorporated to a non-sensitive hydrophilic colloidal layer 
between the support and an emulsion layer closest to the support. 
The silver halide used the present invention may be spectrally sensitized 
by the use of conventional sensitizing dye(s). Combined use of sensitizing 
dyes used for super-sensitization of an internal latent image forming 
silver halide emulsion and a negative type silver halide emulsion is also 
useful for the silver halide emulsion of the present invention. With 
regard to sensitizing dyes, Research Disclosure (hereinafter, abbreviated 
as RD) 15162 and 17643 are referred. 
To the photographic material according to the present invention, it is 
preferable to add compounds which adjust the gradation of the toe portion 
of a characteristic curve. The preferable compounds are those represented 
by Formula [AO-II] described in JP-A No. 6-95283, page 17. As an example 
of preferable compounds, compounds II-1 through II-8 described on page 18 
of the above-mentioned specification are given. 
The added amount of the above-mentioned [AO-II] is preferably 0.001 to 0.50 
g/m.sup.2, and more preferably 0.005 to 0.20 g/m.sup.2. The compound may 
be used singly or in combination. In addition, a quinone derivative having 
a 5 or more carbon atoms may be added to the compound of [AO-II]. However, 
in any cases, the amount used is preferably in a range of 0.001 through 
0.50 g/m.sup.2 in total. Fogging treatment in the internal latent image 
type direct positive type image formation used in the present invention 
preferably may be conducted by providing overall exposure or by the use of 
a compound producing a fogging nucleus, i.e., a fogging agent. 
The overall exposure process is conducted by exposing a photographic 
material uniformly and overall after immersing the imagewise exposed 
photographic material into a developing solution or other aqueous 
solutions, or wetting therewith. Here, as a light source used, any light 
source that has a light-sensitive wavelength range of the photographic 
photographic material may be used. In addition, a high intensity light 
such as a flash may be given for a short time, or a low intensity light 
may be used for a period of longer time. In addition, the time of the 
overall exposure can be varied widely depending of the kind of the 
photographic photographic material, photographic processing conditions and 
the kind of light source used so that superior positive images can be 
obtained. It is still more preferable that the overall exposure is gived 
in an amount within a given range, in combination with with the 
photographic material. Ordinarily, when exposure amount is excessively 
given, an increase of the minimum density and desensitization result, 
which tends to deteriorate image quality. As a technology of a fogging 
agent usable in the present invention, the technology described in JP-A 
No. 6-95283, page 18, right column, line 39 through page 19, left column, 
line 41 is preferable. 
It is preferable to incorporate a fluorescent brightening agent into the 
photographic material of the present invention and/or a processing 
solution which processes the photographic material of the present 
invention in terms of improving white background. 
The developing solution, the bleach-fixing solution and the stabilizing 
solution can process a photographic material continuously while 
respectively replenishing the developing solution, the bleaching solution, 
the bleach-fixing solution and the stabilizing solution. In the present 
invention, the replenishing rate of the developing solution is preferably 
700 cc or less and more preferably 500 cc or less per 1 m.sup.2 of the 
photographic material. In such cases, the present invention provides 
effective result. In the case of other processing solutions too, the 
replenishing amount of the developing solution is preferably 700 cc or 
less and more preferably 500 cc or less per 1 m.sup.2 Of the photographic 
material. In such cases, the present invention can provide effective 
result. The preferred developing agent usable in the developing solution 
for developing the photographic material of the present invention include 
ordinary silver halide developing agents such as hydroquinone, 
hydroxybenzenes, aminophenols, 3-pyrazolones, ascorbic acid and its 
derivatives, reductones, phenylenediamines, and mixtures thereof. 
Specifically, cited are hydroquinone, aminophenol, N-methylaminophenol, 
1-phenyl-3-pyrazolidone, 1-phenyl-4,4-dimethyl-3-pyrazolidone, 
1-phenyl-4-methyl-4-hydroxymethyl-3-pyrazolidone, ascorbic acid, 
N,N-diethylaminotoluidine, 
4-amino-3-methyl-N-ethyl-N-(p-methanesulfonamidoethyl)-aniline, 
4-amino-3-methyl-N-ethyl-N-(.beta.-hydroxyethyl)aniline, 
4-amino-N-ethyl-N-(.beta.-hydroxyethyl)aniline and 
4-amino-3-methyl-N-ethyl-N-(.gamma.-hydroxypropyl)aniline. 
It is also possible to incorporate any of these anti-fogging agents into 
the silver halide emulsion to have the anti-fogging agent reacted with the 
silver halide while immersed in a high pH aqueous solution. 
The developing solution used in the present invention may further contain a 
specific fogging agent and the development restrainer. Alternatively, it 
is possible to arbitrarily incorporate such photographic additives used 
for a developing solution into the component layer(s) of the photographic 
photographic material. 
For the silver halide photographic photographic material in the present 
invention there may be used any of known photographic additives. 
The above-referred to known photographic additives include the following 
compounds described in Research Disclosure RD 17643 and RD 18716. 
______________________________________ 
RD 17643 
Page Section Page Section RD 1 Additives 
______________________________________ 
Chemical sensitizer 
23 III 648 upper right 
Sensitizing dye 23 IV 648 upper right 
Development accelerator 29 XXI 648 upper right 
Antifoggant 24 VI 649 lower right 
Stabilizer 24 VI 649 lower right 
Antistaining agent 25 VII 650 left to right 
Image stabilizer 25 VII 
UV absorbent 25-26 VII 649 right to 
650 left 
Filter dye 25-26 VII 649 right to 
650 left 
Brightening agent 24 V 
Hardener 26 X 651 right 
Coating aid 26-27 XI 650 right 
Surfactant 26-27 XI 650 right 
Plasticizer 27 XII 650 right 
Lubricating agent 27 XII 650 right 
Antistatic agent 27 XII 650 right 
Matting agent 28 XVI 650 right 
Binder 29 IX 651 right 
______________________________________ 
Cited as a support usable in the light-sensitive invention of the present 
invention are those described in the above-mentioned RD 17643, page 28 and 
RD 18716, page 647. Suitable supports include polymer films and papers, 
which may be provided with additional processing to enhance adhesion and 
anti-static properties. 
To form an image using the photographic material of the present invention, 
it is preferable to employ a light source unit scanning exposure type 
automatic processing machine. As practical example of such equipment or 
system for forming a specifically preferable image, Konsensus L, Konsensus 
570 and Konsensus II are cited. 
It is preferable to apply the present invention to a photographic material 
wherein a developing agent is not incorporated in the photographic 
material. Specifically, it is preferable to apply the present invention to 
the photographic material having a reflective support to form an image for 
direct visual stimulation, cited, for example is the photographic material 
for color proofs.

EXAMPLES 
The present invention will be further explained in detail based on examples 
but embodiments of the present invention are not limited to these 
examples. 
Example 1 
Preparation of Emulsion EM-P1 
To an aqueous ossein gelatin solution at a controlled temperature of 
40.degree. C. were simultaneously added both an aqueous ammoniacal silver 
nitrate solution and an aqueous potassium bromide solution in a controlled 
double-jet precipitation process, whereby a cubic silver chlorobromide 
core grain emulsion having an average grain diameter of 0.30 .mu.m was 
obtained. During addition, the pH and pAg were controlled so as to form 
cubic crystal grains. 
To the obtained core grain emulsion further were simultaneously added an 
aqueous ammoniacal silver nitrate solution and an aqueous potassium 
bromide and sodium chloride solution (at a molar KBr:NaCl ratio of 50:50) 
in the controlled double-jet precipitation process to continue formation 
of a shell phase to cover over the core grain of the above emulsion until 
reached the average grain diameter of 0.42 .mu.m. During addition, the pH 
and pAg were controlled so that cubic grains were obtained. 
After subjecting to washing to remove water-soluble salts, gelatin was 
added thereto to obtain emulsion EM-P1. The distribution width of the 
grain diameter of the emulsion EM-1 was 8%. 
Preparation of Emulsion EM-P2 
To an aqueous ossein gelatin solution at a controlled temperature of 
40.degree. C. were simultaneously added both an aqueous ammoniacal silver 
nitrate solution and an aqueous potassium bromide and a sodium chloride 
solution (at a molar KBr:NaCl ratio of 95:5) in the controlled double-jet 
precipitation process, whereby a cubic silver chlorobromide grain emulsion 
having an average grain diameter of 0.18 .mu.m was obtained. During 
addition, the pH and pAg were also controlled so that cubic silver halide 
grains can be obtained. To the core emulsion thus prepared were further 
simultaneously added an aqueous ammoniacal silver nitrate solution and an 
aqueous potassium bromide and a sodium chloride solution (at a molar 
KBr:NaCl ratio of 40:60) in the controlled double-jet precipitation 
process to form a shell phase until reached an average grain diameter of 
0.25 .mu.m. During addition, the pH and pAg were controlled so that cubic 
silver halide grains can be obtained. After the above prepared emulsion 
was subjected to washing to remove water-soluble salts, gelatin was added 
thereto to obtain emulsion EM-P2. The distribution width of the grain 
diameters of the emulsion EM-P2 was 8%. 
Preparation of Blue-sensitive Silver Halide Emulsion 
Emulsion EM-P1 was optimally spectral-sensitized by adding a sensitizing 
dye BS-1, followed by addition of compound T-1 in an amount of 100 mg per 
mol of silver to obtain a blue-sensitive emulsion EM-B1. 
Preparation of Green-sensitive Silver Halide Emulsion 
A green-sensitive emulsion EM-G1 was prepared in the same manner as in the 
blue-sensitive emulsion Em-B1, except that in place of BS-1, sensitizing 
dye GS-1 was added to emulsion EM-P2 to optimally perform spectral 
sensitization. 
Preparation of Red-sensitive Silver Halide Emulsion 
A red-sensitive emulsion EM-R1 was prepared in the same manner as in the 
blue-sensitive emulsion Em-B1, except that in place of BS-1, sensitizing 
dyes RS-1 and RS-2 were added to emulsion EM-P2 to optimally perform 
spectral sensitization. 
Preparation of Infrared-sensitive Silver Halide Emulsion 
An infrared-sensitive emulsion EM-IR was prepared in the same manner as in 
the blue-sensitive emulsion Em-B1, except that in place of BS-1, a 
sensitizing dye IRS-1 was added to emulsion EM-P1 to optimally perform 
spectral sensitization. It was proved that the emulsion EM-P2 had a 
spectral sensitivity maximum at the wavelength of 765 nm. 
T-1: 4-hydroxy-6-methyl-1,3,3a,7-tetrazaindene 
On a paper pulp reflective support of 110 pm thickness in which a high 
density was laminated on one side and polyethylene containing a dispersed 
anatase type titanium oxide in a given amount of 15 weight % on the other 
side, using each of emulsions EM-B1, EM-G1, EM-R1 and EM-IR, each layer 
having the following constitution was coated on a side having the 
polyethylene layer containing titanium oxide, and on the opposite side, 
6.00 g/m.sup.2 of gelatin and 0.65 g/m.sup.2 of a silica matting agent 
were coated. Thus, multi-layered silver halide color photographic 
photographic material Samples 1-1 to 1-7 were prepared. In this case, as a 
hardener, H-1 and H-2 were added. As a coating aid and a dispersion aid, 
surfactants SU-1, SU-2 and SU-3 were added. 
SU-1: Sodium di-2-ethylhexyl sulfosuccinate 
SU-2: Sodium di(2,2,3,3,4,4,5,5-octafluoropentyl) sulfosuccinate 
SU-3: Sodium tri-i-propylnaphthalenesulfonate 
H-1: 2,4-Dichloro-6-hydroxy-s-triazine sodium salt 
H-2: Tetrakis(vinylsulfonylmethyl)methane 
______________________________________ 
Layer Constitution Coating wt(g/m.sup.2) 
______________________________________ 
12th Layer 
Gelatin 1.20 
(UV absorbing UV absorbent (UV-1) 0.07 
layer) UV absorbent (UV-2) 0.02 
UV absorbent (UV-3) 0.07 
Silica matting agent 0.01 
11th Layer Gelatin 0.92 
(Blue-sensitive Blue-sensitive emulsion (EM-B1) 0.33 
layer) Magenta coupler (M-1) 0.20 
Yellow coupler (Y-3) 0.05 
Restrainer (T-1) 0.002 
Restrainers (T-2, T-3, T-4) 
(mol ratio 1:1:1) 0.0004 
Anti-staining agent (HQ-1) 0.03 
High boiling solvent (SO-1) 0.31 
10th Layer Gelatin 0.40 
(Intermediate Anti-staining agent (HQ-2) 0.02 
layer) Anti-staining agent(HQ-3) 0.01 
High boiling solvent (SO-2) 0.005 
9th Layer Gelatin 0.08 
(Yellow colloidal Yellow colloidal silver 0.09 
layer) Antistaining agent (HQ-2) 0.02 
Antistaining agent (HQ-3) 0.01 
High boiling solvent (SO-2) 0.005 
Polyvinyl pyrrolidone 0.04 
8th Layer Gelatin 0.04 
(Intermediate Antistaining agent (HQ-2) 0.02 
layer) Antistaining agent (HQ-3) 0.01 
High boiling solvent (SO-2) 0.005 
7th Layer Gelatin 1.20 
(Green-sensitive Green-sensitive emulsion (EM-G1) 0.38 
layer) Yellow coupler (Y-1) 0.51 
Magenta coupler (M-1) 0.11 
High boiling solvent (SO-3) 0.31 
Antistaining agent (HQ-1) 0.06 
Restrainer (T-1) 0.004 
Restrainers (T-2, T-3, T-4) 
(mol ratio 1:1:1) 0.0002 
6th Layer Gelatin 0.50 
(Intermediate Antistaining agent (HQ-2) 0.04 
layer) Antistaining agent (HQ-3) 0.02 
High boiling solvent (SO-2) 0.01 
5th Layer Gelatin 1.75 
(Cyan layer) Red-sensitive emulsion (EM-R1) 0.25 
Green-sensitive emulsion (EM-G1) 0.24 
Cyan coupler (C-100) 0.35 
High boiling solvent (SO-4) 0.33 
High boiling solvent (SO-5) 0.33 
Antistaining agent (HQ-1) 0.035 
Restrainer (T-1) 0.0015 
Restrainers (T-2, T-3, T-4) 
(mol ratio 1:1:1) 0.0004 
4th Layer Gelatin 0.70 
(Intermediate Antistaining agent (HQ-2) 0.04 
layer) Antistaining agent (HQ-3) 0.02 
High boiling solvent (SO-2) 0.01 
Antiirradiation dye (AI-1) 0.03 
Antiirradiation dye (AI-2) 0.03 
3rd Layer Gelatin 1.10 
(Red sensitive Red-sensitive emulsion (EM-IR1) 0.40 
layer) Yellow coupler (Y-1) 0.43 
Yellow coupler (Y-2) 0.10 
High boiling solvent (SO-1) 0.43 
Antistaining agent (HQ-1) 0.05 
Restrainer (T-1) 0.006 
Restrainers (T-2, T-3, T-4) 
(mol ratio 1:1:1) 0.0004 
2nd Layer Gelatin 0.40 
(Intermediate Antistaining agent (HQ-2) 0.01 
layer) Antistaining agent (HQ-3) 0.005 
High boiling solvent (SO-2) 0.003 
Antiirradiation dye (AI-4) 0.05 
Brightener solid fine particles 1.40 
(F-10) 
1st Layer Gelatin 0.60 
(Antihalation Latex (LA-1) 0.12 
layer) Black colloidal silver 0.03 
Polyvinyl pyrrolidone 0.10 
Titanium oxide Table 1 
Support Polyethylene laminated paper 
(containing minute amount of 
colorant) 
______________________________________ 
The silver coating weight in the above is in silver equivalents. 
SO-1: Tri(n-octyl)phosphine oxide 
SO-2: Di(i-decyl)phthalate 
HQ-1: 2,5-Di(t-butyl)hydroquinone 
HQ-2: 2,5-Di[(1,1-dimethyl-4-hexyloxycarbonyl)butyl]-hydroquinone 
HQ-3: Mixture of 2,5-di-sec-dodecylhydroquinone, 
2,5-di-sec-tetradecylhydroquinone and .sup.2 
-sec-dodecyl-5-sec-tetradecylhydroquinone (wt. ratio 1:1:2) 
T-2: 1-(.sup.3 -Acetoamidophenyl)-5-mercaptotetrazole 
T-3: N-Benzyladenine 
T-4: .sup.2 -Mercaptobenzothiazole 
##STR4## 
TABLE 1 
______________________________________ 
Sample Coverage 
No. Titanium Oxide (g/m.sup.2) 
______________________________________ 
1-1 None 0.0 
1-2 Anatase type titanium oxide with av. size of 1.0 
0.15 .mu.m 
1-3 Rutile type titanium oxide with av. size of 0.20 .mu.m 1.0 
1-4 Anatase type titanium oxide with av. size of 1.0 
0.29 .mu.m 
1-5 Rutile type titanium oxide with av. size of 0.29 .mu.m 1.0 
1-6 Rutile type titanium oxide with av. size of 0.35 .mu.m 1.0 
1-7 Rutile type titanium oxide with av. size of 0.75 .mu.m 1.0 
______________________________________ 
The obtained Sample 1-1 to 1-7 each were exposed to light under the 
following exposure condition-Y through a yellow halftone original in close 
contact therewith, then exposed to light under the following exposure 
condition-M through a magenta halftone original in close contact 
therewith, then further exposed to light under the following exposure 
condition-C through a cyan halftone original in close contact therewith 
and then further exposed to light under the following exposure condition-Y 
through and a black halftone original in contact therewith. In the 
halftone originals employed above, images having a halftone percentage of 
50% at 175 lines/inch (hereinafter, also referred to as a middle dot) were 
included in each of the yellow, magenta, cyan and black originals so that 
reproducibility of the image with 50% dots was evaluated with respect to 
the dot percentage. Further, each original included a portion in which the 
dot percentage was varied so as to evaluate reproducibility of small dots. 
Thus-exposed samples were each processed according to the process as shown 
below to obtain dye images comprised of halftone dots. 
Exposure condition-Y 
Each photographic material sample was exposed, through infrared filters 
(LEF Filters 026 and 363 were employed one over the other) and an ND 
filter, to an infrared light source for 0.3 seconds. Exposure was adjusted 
by varying the ND filter density so that after processing, the yellow 
halftone dot original with the dot percentage of 50% gave dots with the 
dot percentage of 60% (Exposure condition-Y60) or dots with the dot 
percentage of 65% (Exposure condition-Y65). 
Exposure condition-M 
Each photographic material sample was exposed, through blue filters 
(Wratten filter No. 47B) and an ND filter, to a white light source for 0.3 
seconds. Exposure was adjusted by varying the ND filter density so that 
after processing, the magenta halftone dot original with the dot 
percentage of 50% gave dots with the dot percentage of 60% (Exposure 
condition-M60) or dots with the dot percentage of 65% (Exposure 
condition-M65). 
Exposure condition-C 
Each photographic material sample was exposed, through red filters (Wratten 
filter No. 26) and an ND filter, to a white light source for 0.3 seconds. 
Exposure was adjusted by varying the ND filter density so that after 
processing, the cyan halftone dot original with the dot percentage of 50% 
gave dots with the dot percentage of 60% (Exposure condition-C60) or dots 
with the dot percentage of 65% (Exposure condition-C65). 
Exposure condition-K 
Each photographic material sample was exposed, through green filters 
(Wratten filter No. 58) and an ND filter, to a white light source for 0.3 
seconds. Exposure was adjusted by varying the ND filter density so that 
after processing, the cyan halftone dot original with the dot percentage 
of 50% gave dots with the dot percentage of 60% (Exposure condition-K60) 
or dots with the dot percentage of 65% (Exposure condition-K65). 
In the exposure condition-Y, an infrared fluorescent lamp emitting infrared 
radiation was employed as an infrared light source. The white light source 
employed in the exposure conditions-M, C and K was a daylight fluorescent 
lamp. 
The samples were each processed according to the following Process-1 (fresh 
solution processing). The fog exposure was carried out as follows. The 
sample was immersed in a 3 mm thick developing solution and subjected to 
uniform overall exposure. In the Process-1, Sample 1-6 was 
running-processed until the replenishing amount of a developing solution 
replenisher reached three times the content of the developing solution 
tank, and thereafter, samples were each processed using the developing 
solution, bleach-fixing solution and stabilizing solution which were 
obtained after running processing. 
The obtained images of each sample were evaluated with respect to yellow, 
magenta and cyan densities of the white background at the time the dot 
percentage of medium dots was 65% and yellow, magenta and cyan densities 
of the white background at the time the dot percentage of medium dots was 
60%, and with respect to small dot reproducibility of yellow, magenta, 
cyan and black images. With respect to the densities of the white 
background, difference between the white background density at the dot 
percentage of 65% and that at the dot percentage of 60% was shown as white 
background variation in Table 2. 
______________________________________ 
Process-1 Processing step 
Temperature 
Time 
______________________________________ 
Immersing in developing 
37.degree. C. 
12 seconds 
solution 
Light fogging -- 12 seconds 
Developing 37.degree. C. 95 seconds 
Bleach-fixing 35.degree. C. 45 seconds 
Stabilizing 25-30.degree. C. 90 seconds 
Drying 60-85.degree. C. 40 seconds 
______________________________________ 
Compositions of the processing solutions 
Color developing solution 
______________________________________ 
Benzyl alcohol 15.0 ml 
Ceric sulfate 0.015 g 
Ethylene glycol 8.0 ml 
Potassium sulfite 2.5 g 
Potassium bromide 0.6 g 
Sodium chloride 0.2 g 
Potassium carbonate 25.0 g 
T-1 0.1 g 
Hydroxylamine sulfate 5.0 g 
Sodium diethylenetriaminepentaacetate 2.0 g 
4-amino-N-ethyl-N-(.beta.-hydroxyethyl)aniline sulfate 4.5 g 
Brightening agent (4,4'-diaminostilbene- 1.0 g 
disulfonic acid derivative) 
Potassium hydroxide 2.0 g 
Diethylene glycol 15.0 ml 
Water to make 1000 ml 
The pH was adjusted to 10.15. 
______________________________________ 
Bleach-fixing solution 
______________________________________ 
Ferric ammonium diethylenetriaminepentaacetate 
90.0 g 
Diethylenetrimainepentaacetic acid 3.0 g 
Ammonium thiosulfate (70% aqueous solution) 180.0 ml 
Ammonium sulfite (40% aqueous solution) 27.5 ml 
3-mercapto-1,2,4-triazole 0.15 g 
Water to make 1000 ml. 
______________________________________ 
The pH was adjusted to 7.1 with potassium carbonate or glacial acetic acid 
Stabilizing solution 
______________________________________ 
O-Phenylphenol 0.3 g 
Potassium sulfite (50% aqueous solution) 12 ml 
Ethylene glycol 10.0 g 
1-hydroxyethylidene-1,1-diphosphonic acid 2.5 g 
Bismuth chloride 0.2 g 
Zinc sulfate, heptahydrate 0.7 g 
Ammonium hydroxide (28% aqueous solution) 2.0 g 
Polyvinylpyrrolidone K-17 0.2 g 
Brightening agent (4,4'-diaminostilbene- 2.0 g 
disulfonic acid derivative) 
Water to make 1 liter. 
______________________________________ 
The pH was adjusted to 7.5 with ammonium hydroxide or sulfuric acid. The 
stabilization treatment was performed using the double bath counterflow 
system. 
The following are the prescriptions of replenishers necessary for 
conducting a continuous run of processing. 
Color developing solution replenisher 
______________________________________ 
Benzyl alcohol 18.5 ml 
Ceric sulfate 0.015 g 
Ethylene glycol 10.0 ml 
Potassium sulfite 2.5 g 
Potassium bromide 0.3 g 
Sodium chloride 0.2 g 
Potassium carbonate 25.0 g 
T-1 0.1 g 
Hydroxylamine sulfate 5.0 g 
Sodium diethylenetriaminepentaacetate 2.0 g 
4-Amino-N-ethyl-N-(.beta.-hydroxyethyl) aniline sulfate 5.4 g 
Brightening agent (4,42-diaminostilbene- 1.0 g 
disulfonic acid derivative) 
Potassium hydroxide 2.0 g 
Diethylene glycol 18.0 ml 
Water to make 1 liter, 
The pH was adjusted to 10.35. 
______________________________________ 
Bleach-fixing solution replenisher 
The same as the foregoing bleach-fixing bath. 
Stabilizing solution replenisher 
The same as the foregoing stabilizing bath. 
The replenishing rate of each of the developing solution replenisher, 
bleach-fixing solution replenisher or stabilizing solution replenisher was 
320 ml per m.sup.2 of photographic material. Using Konsensus 570 available 
from Konica Corporation, color proofs composed of halftone images were 
prepared. The processing was continuously conducted until the total amount 
of color developing solution replenisher replenished reaches an amount 
that is 3 times the solution amount of the color developing tank. 
TABLE 2 
______________________________________ 
Density Variation of 
White Background Small dot Reproducibility* 
Sample No. 
Y M C Y M C BK 
______________________________________ 
1-1 (Comp.) 
0.07 0.05 0.05 6% 5% 5% 5% 
1-2 (Comp.) 0.09 0.09 0.08 5% 4% 4% 4% 
1-3 (Comp.) 0.12 0.09 0.08 4% 4% 4% 4% 
1-4 (Comp.) 0.09 0.09 0.08 6% 5% 5% 5% 
1-5 (Comp.) 0.09 0.09 0.08 6% 5% 5% 5% 
1-6 (Inv.) 0.03 0.02 0.02 4% 3% 3% 3% 
1-7 (Inv.) 0.03 0.02 0.02 4% 4% 3% 3% 
______________________________________ 
*at the time medium of dots with the dot percentage of 65% being 
reproduced 
As can be seen from Table 2, inventive samples were each low in variation 
of the white background density, even when the dot percentage of medium 
dots was varied, and having preferable characteristics in view of superior 
small dot reproducibility. 
Example 2 
Samples 2-1 to 2-3 were prepared in a manner similar to Sample 1-6 of 
Example 1, except that the coverage of the antiirradiation dye (AI-4) used 
in the 2nd layer was varied so that an unprocessed sample had a reflection 
density measured at a wavelength of 765 nm, as shown in Table 3. Each 
sample was processed in the same manner as in Example 1 and obtained 
images were evaluated with respect to reproducibility of yellow small 
dots. 
TABLE 3 
______________________________________ 
Small Dot Reproducibility* 
Sample No. Reflection Density Y 
______________________________________ 
2-1 0.92 4% 
2-2 1.07 3.5% 
2-3 1.15 3% 
______________________________________ 
*: at the time of medium dots with the dot percentage of 65% being 
reproduced 
As can be seen from Table 3, unprocessed samples having a reflection 
density of not less than 1.0 were superior in the small dot 
reproducibility. 
Example 3 
Sample 3-1 was prepared in a manner similar to Sample 2-3 of Example 2, 
except that cyan coupler, C-100 used the 5th layer was replaced by C-45 
with a coverage of 0.24 g/m.sup.2. Samples were each processed and 
evaluated in the same manner as in Example 1. Results thereof are shown in 
Table 4. 
TABLE 4 
______________________________________ 
Density Variation of 
White Background Small dot Reproducibility* 
Sample No. 
Y M C Y M C BK 
______________________________________ 
2-3 (Inv.) 
0.03 0.02 0.02 3% 3% 3% 3% 
3-1 (Inv.) 0.03 0.02 0.00 3% 3% 2% 3% 
______________________________________ 
*at the time of medium dots with the dot percentage of 65% being 
reproduced 
As can be seen from Table 4, the use of the cyan coupler preferably used in 
the invention led to an improvement in the white background variation and 
small dot reproducibility.