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photographic processing

 
 
Columbia Encyclopedia: photographic processing
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photographic processing, set of procedures by which the latent, or invisible, image produced when a photographic film is exposed to light is made into a permanent visible image.

Creation of the Latent Image on the Film

An emulsion holding grains of photosensitive chemical compounds called silver halides is spread over a film or other material. Light coming through the camera lens from an object being photographed strikes certain areas of the film, rendering the silver halide grains in those areas unstable. This creates an invisible, or latent, image of the object on the film. The areas of the latent image that receive the most light contain the largest number of unstable grains. Upon development they become the darkest areas of the visible image. Conversely, areas that receive little light form the bright parts of the visible image.

Processing the Negative

Because of the reversal of dark and bright areas from the latent image to the visible image, the visible image is often called a negative. The most common method of making the image visible is to bathe it in a chemical developer that reduces the unstable silver halide grains to black metallic silver, which forms the image. In addition to the reducing agent, which is generally an organic compound such as a phenol or an amine, the typical developer contains additives that cause development to go on at a desired rate, prevent the reducing agent from being destroyed by the air, and keep unexposed silver halide from fogging the film. Each developer is generally designed to be used with particular film emulsions and to produce certain desired effects, such as fineness of grain in the finished image.

After development the negative must be stabilized, or fixed, so that it will no longer be sensitive to light. In fixing, the unexposed silver halide grains are removed by immersion in a water solution of sodium or aluminum thiosulfate. Between the developing and fixing processes the negative may be placed in an acid bath to neutralize excess alkali left by the developer. After fixing, the negative is washed and dried. Next the negative may be subjected either to intensification, a process in which additional silver is deposited in exposed areas to increase the contrast in the image, or to reduction, a process in which silver is removed to decrease the contrast. Toning is a process in which a photographic image is treated to change its color, as by changing the deposited silver to silver sulfide or causing a colored metal salt to form along with the silver.

Production of the Print

The negative may be used to produce a positive image, often called a print, or photograph, in which the light and dark areas of the object and the image correspond. The positive is produced by first projecting the negative onto a photosensitive paper. When this is done by direct contact, i.e., placing the negative and photosensitive paper together, the positive produced is the same size as the negative. When a system of lenses is interposed, the positive image may be enlarged or reduced. After this the latent image on the photosensitive paper is developed by a process similar to that used on the negative.

In most color films there are three layers of emulsions, each sensitive to a different color of light and each capable of forming a different color dye when developed. There are many development processes in use, but nearly all use paraphenylene-diamine derivatives. In one process the exposed film is made into a positive color transparency, in another a negative from which positive prints are produced. In both processes the finished product contains three layers, each one containing an image in a different color. The superposition of these images reproduces the colors of the photographed object.

Polaroid photography uses a more complex process, by which the image diffuses from the top layer, where it is originally captured, to lower layers where it activates appropriate dyes to recreate the recorded image (see Land, Edwin).

Bibliography

See A. Feininger, Darkroom Techniques (1974); M. J. Langford, Basic Photography (1977); H. J. Walls and G. S. Attridge, Basic Photo Science (1978); G. T. Eaton, Photographic Chemistry (1981).

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Wikipedia: Photographic processing
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Photographic processing is the chemical means by which photographic film and paper is treated after photographic exposure to produce a negative or positive image. Photographic processing transforms the latent image into a visible image, makes this permanent and renders it insensitive to light.

All processes based upon the gelatin-silver process are similar, regardless of the film or paper's manufacturer. Exceptional variations include instant films such as Polaroid and thermally developed films.

Kodachrome requires Kodak's proprietary K-14 process, and can only be processed by a single facility, located in Kansas, USA.

Ilfochrome materials use the dye destruction process.

Contents

Common processes

All film and paper is treated in a series of chemical baths, which are closely monitored and maintained at a specific temperature and treatment time. Developer baths are most sensitive to deviations from the standard time and temperature of treatment; other baths are less sensitive.

Black and white negative materials

  • The film may be soaked in water to swell the gelatin layer.
  • The developer converts the latent image to metallic silver.[1]
  • A stop bath, typically a dilute solution of acetic acid or citric acid, halts the action of the developer. A rinse with clean water may be substituted.

In modern automatic processing machines, this step is replaced by mechanical squeegee or pinching rollers. These treatments remove much of the carried-over alkaline developer, and the acid, when used, neutralizes the alkalinity to reduce the contamination of the fixing bath with the developer.

  • The fixer makes the image permanent and light-resistant by dissolving any remaining silver halide salts. Fixer is sometimes called "hypo," a misnomer originating from casually shortened form of the alchemist's name hyposulphite. Neither "hyposulphite," "hyposulfite" nor "hypo" is used to mean thiosulfate in modern chemistry.[2]
  • Washing in clean water removes any remaining fixer. Residual fixer can corrode the silver image, leading to discolouration, staining and fading. The washing time can be reduced and the fixer more completely removed if a hypo clearing agent is used after the fixer.
  • Film may be rinsed in a dilute solution of a non-ionic wetting agent to assist uniform drying, which eliminates drying marks caused by hard water. (In very hard water areas, a pre-rinse in distilled water may be required - otherwise the final rinse wetting agent can cause residual ionic calcium on the film to drop out of solution, causing spotting on the negative.)
  • Film is then dried in a dust-free environment, cut and placed into protective sleeves.
  • Once the film is processed, it is then referred to as a negative. The next step in photographic processing is to enlarge the negative.
  • The negative will be placed in an enlarger and mirrored onto a sheet of photo paper. There are many different techniques that can be used during the enlargement process. Two examples of enlargement techniques are dodging and burning.

Black & white reversal processing

This process has three additional stages:

  • Following the stop bath, the film is bleached to remove the developed negative image. The film then contains a latent positive image formed from unexposed and undeveloped silver halide salts.
  • The film is fogged, either chemically or by exposure to light.
  • The remaining silver halide salts are developed in the second developer, converting them into a positive image.
  • Finally, the film is fixed, washed, dried and cut.[3]

Colour processing

Chromogenic materials use dye couplers to form colour images.

Modern colour negative film is developed with the C-41 process and colour negative print materials with the RA-4 process. These processes are very similar, with differences in the first chemical developer.

The C-41 and RA-4 processes consist of the following steps:

  • The colour developer develops the silver negative image, and byproducts activate the dye couplers to form the colour dyes in each emulsion layer.
  • A rehalogenising bleach converts the developed silver image into silver halides.
  • A fixer removes the silver salts.
  • The film is washed, stabilised, dried and cut. [4]

In the RA-4 process, the bleach and fix are combined. This is optional, and reduces the number of processing steps.[5]

Transparency films, except Kodachrome, are developed using the E-6 process, which has the following stages:

  • A black and white developer develops the silver in each image layer.
  • Development is stopped with a rinse or a stop bath.
  • The film is fogged in the reversal step.
  • The fogged silver halides are developed and exhausted developing agents couple with the dye couplers in each layer.
  • The film is bleached, fixed, stabilised and dried as described above. [4]

In some old processes, the film emulsion was hardened during the process, typically before the bleach. Such a hardening bath often used aldehydes, such as formaldehyde and glutaraldehyde. In modern processing, these hardening steps are unnecessary because the film emulsion is sufficiently hardened to withstand the processing chemicals.

Further processing

Black and white emulsions both negative and positive, may be further processed. The image silver may be reacted with elements such as selenium or sulphur to increase image permanence and for aesthetic reasons. This process is known as toning.

In selenium toning, the image silver is changed to silver selenide; in sepia toning, the image is converted to silver sulphide. These chemicals are more resistant to atmospheric oxidising agents than silver.

If colour negative film is processed in conventional black and white developer, and fixed and then bleached with a bath containing hydrochloric acid and potassium dichromate solution, the resultant film, once exposed to light, can be redeveloped in colour developer to produce an unusual pastel colour effect.[citation needed]

See also: Photographic print toning

Processing apparatus

Before processing, the film must be removed from the camera and from its cassette, spool or holder in a light-proof room or container.

Small scale processing

A cut-away illustration of a typical light-trap tank used in small scale developing.

In amateur processing, the film is removed from the camera and wound onto a reel in complete darkness (usually inside a darkroom with the safelight turned off or a lightproof bag with arm holes). The reel holds the film in a spiral shape, with space between each successive loop so the chemicals may flow freely across the film's surfaces. The reel is placed in a specially designed light-proof tank (called daylight processing tank or a light-trap tank) where it is retained until final washing is complete.

Sheet films can be processed in trays, in hangers (which are used in deep tanks), or rotary processing drums. Each sheet can be developed individually for special requirements. Stand development, long development in dilute developer without agitation, is occasionally used.

Commercial processing

In commercial processing, the film is removed automatically or by an operator handling the film in a light proof bag from which it is fed into the processing machine. The processing machinery is generally run on a continuous basis with films spliced together in a continuous line. All the processing steps are carried out within a single processing machine with automatically controlled time, temperature and solution replenishment rate. The film or prints emerge washed and dry and ready to be cut by hand. Some modern machines also cut films and prints automatically, sometimes resulting in negatives cut across the middle of the frame where the space between frames is very thin or the frame edge is indistinct, as in an image taken in low light.

Environmental and safety issues

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Many photographic solutions have high chemical and biological oxygen demand (COD and BOD). These chemical wastes are often treated with ozone, peroxide or aeration to reduce the COD in commercial laboratories.

Exhausted fixer and to some extent rinse water contain silver thiosulfate complex ions. They are far less toxic than free silver ion, and they become silver sulfide sludge in the sewer pipes or treatment plant. However, the maximum silver concentration in discharge is very often tightly regulated. Silver is also a somewhat precious resource. Therefore, in most large scale processing establishments, exhausted fixer is collected for silver recovery and disposal.

Many photographic chemicals use non-biodegradable compounds, such as EDTA, DTPA, NTA and borate. EDTA, DTPA, and NTA are very often used as chelating agents in all processing solutions, particularly in developers and washing aid solutions. EDTA and other polyamine polycarboxylic acids are used as iron ligands in color bleach solutions. These are relatively nontoxic, and in particular EDTA is approved as a food additive. However, due to poor biodegradability, these chelating agents are found in alarmingly high concentrations in some water sources from which municipal tap water is taken[citation needed]. Water containing these chelating agents can leach metal from water treatment equipment as well as pipes. This is becoming an issue in Europe and some parts of the world[citation needed].

Another non-biodegradable compound in common use is surfactant. A common wetting agent for even drying of processed film uses Union Carbide/Dow Triton X-100 or octylphenol ethoxylate. This surfactant is also found to have estrogenic effect and possibly other harms to organisms including mammals[citation needed].

Development of more biodegradable alternatives to the EDTA and other bleaching agent constituents were sought by major manufacturers, until the industry became less profitable when the digital era began.

In most amateur darkrooms, a popular bleach is potassium hexacyanoferrate (III) (common name potassium ferricyanide). This compound decomposes in the waste water stream to liberate cyanide gas[citation needed]. Other popular bleach solutions use potassium dichromate (a hexavalent chromium) or permanganate. Both ferricyanide and dichromate are tightly regulated for sewer disposal from commercial premises in some areas.

Borates, such as borax (sodium tetraborate), boric acid and sodium metaborate, are toxic to plants, even at a concentration of 100 ppm. Many film developers and fixers contain 1 to 20 g/L of these compounds at working strength. Most non-hardening fixers from major manufacturers are now borate-free, but many film developers still use borate as the buffering agent. Also, some, but not all, alkaline fixer formulae and products contain a large amount of borate. New products should phase out borates, because for most photographic purposes, except in acid hardening fixers, borates can be substituted with a suitable biodegradable compound.

Developing agents are commonly hydroxylated benzene compounds or aminated benzene compounds, and they are harmful to humans and experimental animals. Some are mutagens. They also have a large chemical oxygen demand (COD). Ascorbic acid and its isomers, and other similar sugar derived reductone reducing agents are a viable substitute for many developing agents. Developers using these compounds were actively patented in the US, Europe and Japan, until 1990s but the number of such patents is very low since late-1990s, when the digital era began.

References

  1. ^ Wall, 1890, p30 - 63
  2. ^ Wall, 1890, p 88 - 89
  3. ^ Photographic Almanac, 1956, P149 - 155
  4. ^ a b Langford, Michael (2000). Basic Photography. Oxford: Focal Press. pp. 210; 215-216. ISBN 0 240 51592 7. 
  5. ^ Photographic Almanac, 1956, p429- 423
  • Wall, E.J. (1890). Dictionary of Photography. London: Hassel, Watson and Viney Ltd. 
  • The British Journal (1956). Photographic Almanac. London: Henry Greenwood and Co Ltd. 

See also

External links


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