Sabattier effect

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The Sabatier effect, also known as pseudo-solarization (or pseudo-solarisation) and erroneously referred to as the Sabattier effect, is a phenomenon in photography in which the image recorded on a negative or on a photographic print is wholly or partially reversed in tone. Dark areas appear light or light areas appear dark. Solarization and pseudo-solarization are quite distinct effects. Over time, the "pseudo" has been dropped in many photographic darkroom circles and discussions, [1] but the effect that is meant is the Sabattier effect and not the solarization by extreme overexposure (see below).

Contents

Background

Initially, the term "solarization" was used to describe the effect observed in cases of extreme overexposure of the photographic film or plate in the camera.

The effect generated in the dark room was then called pseudo-solarization. Spencer [2] defines the Sabattier effect as: "Partial image reversal produced by brief exposure to white light of a partly developed silver halide image". Many other ways of chemical [3] and actinic radiation "exposure" can be utilised for the partial image reversal. [4] The use of chemicals for image reversal is also known as 'chemical fogging'. [5] The SPSE Handbook of Photographic Science and Engineering describes the effect as follows: If a film that has been exposed, developed, and washed but not fixed is given a second uniform exposure and developed again, an image with strong border effects is obtained, which combines the original image with a reversed (positive) image. [6] Another usable definition is by Wijnekus & Wijnekus: If an exposed, incompletely developed, and washed, but not fixed film is given a second uniform exposure and developed again, a reversal of the original image may be obtained. The reversal may be partial or complete, depending on the relative magnitude of the first and second exposures. [7]

Normal print Pier study straight.jpg
Normal print
Pseudo-solarized print from the same negative Pier study solarised.jpg
Pseudo-solarized print from the same negative

History

The pseudo-solarization effect was described in print by H. de la Blanchère in 1859 in L’Art du Photographe.[ citation needed ] It was described again in 1860 by L.M. Rutherford and C.A. Seely, [8] separately, in successive issues of The American Journal of Photography, and in the same year by Count Schouwaloff in the French publication Cosmos. French scientist Armand Sabatier published 26 October 1860 a process of obtaining direct positives (referencing Count Schouwaloff and Poitevin), [9] but according to the description, this process did not seem to have any connection with the Sabattier effect as no mention was made of any exposure of the collodion plates after development had started. [10] The name of the author was erroneously spelled with double "t" and thus the effect is hence known as the Sabattier effect in most literature. [11] [12] Sabatier described correctly the phenomenon in 1862. [13] [14] However, Sabatier could not find an explanation for the phenomenon. [12]

The effect was usually caused by accidentally exposing an exposed plate or film to light during developing. The artist Man Ray perfected the technique which was accidentally discovered in the darkroom because of fellow artist Lee Miller accidentally exposing his film in the darkroom. It is evident from publications in the 19th century that this phenomenon was discovered many times by many photographers as it tends to occur whenever a light is switched on inadvertently in the darkroom while a film or print is being developed.

Explanation

Whereas many photographic effects have been researched and explained in such a way that most researchers agree upon them, the Sabattier effect does not belong to that group. In general the following facts are accepted by the community of photographic researchers: [12]

In the darkroom

Pseudo-solarization of paper positive in darkroom 1981-fotozirkel-kulturbund-eberswalde-by-RalfR-21-sol2.jpg
Pseudo-solarization of paper positive in darkroom
Pseudo-solarization of paper positive in darkroom Pseudo Solarisation.jpg
Pseudo-solarization of paper positive in darkroom

Careful choice of the amount of light used and the precise moment in development to provide the additional exposure gives rise to different outcomes. However, pseudo-solarization is very difficult to manage to yield consistent results.

As a guide, an exposure of one second to a 25 watt incandescent lamp at two metres distance at around the end of the first minute of a 2-minute development can produce acceptable results. If the exposure is made with the developing print still in the tray of developer, it is important to stop agitation at least 10 seconds prior to exposure to allow any bubbles on the surface to disperse and to ensure that the print is lying flat. Pseudo-solarizing colour prints is more difficult because of the more careful control of temperature and timing that is required and because most amateur processing is undertaken in a processing drum rather than a dish. As lightsource also an enlarger without negative in the carrier can be used.[ better source needed ] In colour photography, different coloured lights can be used to affect pseudo-solarization, but the results become even less predictable.

Using the Sabattier effect it should be obvious that it is very difficult to manage all parameters for yielding consistent and predictable results and therefore other means have been pursued such as Agfacontour and special pseudo-solarizing developers [16] [17]

In scientific photography it was observed that when using photographic films with very high contrast (also known as lith films), the image produced by the Sabattier effect exhibited a multitude of lines of various width, representing a specific amount of exposure within a certain range. This led to the use of the Sabattier effect in the fields of photogrammetry and equidensitometry.

Agfacontour Professional Film

In 1970, Agfa marketed Agfacontour Professional Film, which simplified the process of obtaining consistent results for images that looked similar to pseudo-solarized images and therefore it was widely used in equidensitometry and art. [18] [19] This special purpose film addressed the uncertainty of pseudo-solarisation results.

As of 2002, Agfacontour Film was no longer being produced. [20]

In digital media

Early video synthesiser technologists concerned themselves with achieving arbitrary curves not limited by film chemistry. A goal was to extend the range of pseudo-solarization effects possible to a computer specified curve. They then applied the defined solarization curve to real time video images. A video lookup table was often used to implement this. Using this enhanced solarization technology, still photos could also be passed through a grey scale or colour lookup table with the advantage that the effect could be previewed and progressively improved, instead of a procedure based on darkroom exposure calculations applied on a one time basis to a volatile light sensitive film or print, as described above. This was an especial advantage for creating colour solarizations with 3 primary colours.

Graphs describing pseudo-solarization curves typically place input range of tones on the x axis, with black at 0 and white to the right, and the output range of tones on the y axis with black at 0 and white up. A curve then defines the input to output mapping. Manipulating custom curves in photo-editing programs such as Photoshop provide tools to mimic the Sabattier effect in digital image processing. [1]

A digitally pseudo-solarized color image Spiritual Tree dsc06786 duo nevit.jpg
A digitally pseudo-solarized color image

Related Research Articles

The following list comprises significant milestones in the development of photography technology.

<span class="mw-page-title-main">Agfa-Gevaert</span> Belgian-German imaging company

Agfa-Gevaert N.V. (Agfa) is a Belgian-German multinational corporation that develops, manufactures, and distributes analogue and digital imaging products, software, and systems.

<span class="mw-page-title-main">Reversal film</span> Type of photographic film that produces a positive image on a transparent base

In photography, reversal film or slide film is a type of photographic film that produces a positive image on a transparent base. Instead of negatives and prints, reversal film is processed to produce transparencies or diapositives. Reversal film is produced in various sizes, from 35 mm to roll film to 8×10 inch sheet film.

<span class="mw-page-title-main">Darkroom</span> Room which can be made fully dark to allow for development of photographs and film

A darkroom is used to process photographic film, make prints and carry out other associated tasks. It is a room that can be made completely dark to allow the processing of light-sensitive photographic materials, including film and photographic paper. Various equipment is used in the darkroom, including an enlarger, baths containing chemicals, and running water.

<span class="mw-page-title-main">Gelatin silver process</span> Photographic process

The gelatin silver process is the most commonly used chemical process in black-and-white photography, and is the fundamental chemical process for modern analog color photography. As such, films and printing papers available for analog photography rarely rely on any other chemical process to record an image. A suspension of silver salts in gelatin is coated onto a support such as glass, flexible plastic or film, baryta paper, or resin-coated paper. These light-sensitive materials are stable under normal keeping conditions and are able to be exposed and processed even many years after their manufacture. The "dry plate" gelatin process was an improvement on the collodion wet-plate process dominant from the 1850s–1880s, which had to be exposed and developed immediately after coating.

<span class="mw-page-title-main">Enlarger</span> Specialized transparency projector

An enlarger is a specialized transparency projector used to produce photographic prints from film or glass negatives, or from transparencies.

The science of photography is the use of chemistry and physics in all aspects of photography. This applies to the camera, its lenses, physical operation of the camera, electronic camera internals, and the process of developing film in order to take and develop pictures properly.

<span class="mw-page-title-main">Latent image</span> An invisible image produced by the exposure of a photosensitive material to light.

A latent image is an invisible image produced by the exposure to light of a photosensitive material such as photographic film. When photographic film is developed, the area that was exposed darkens and forms a visible image. In the early days of photography, the nature of the invisible change in the silver halide crystals of the film's emulsion coating was unknown, so the image was said to be "latent" until the film was treated with photographic developer.

<span class="mw-page-title-main">Cross processing</span>

Cross processing is the deliberate processing of photographic film in a chemical solution intended for a different type of film. The effect was discovered independently by many different photographers often by mistake in the days of C-22 and E-4. Color cross processed photographs are often characterized by unnatural colors and high contrast. The results of cross processing differ from case to case, as the results are determined by many factors such as the make and type of the film used, the amount of light exposed onto the film and the chemical used to develop the film. Cross processing has been used in a variety of photographic and cinematographic practices, most notably rising in popularity during the 1990s. Similar effects can also be achieved with digital filter effects.

<span class="mw-page-title-main">ADOX</span>

The ADOX brand for photographic purposes has been used by three different companies since its original conception over one hundred fifty years ago. ADOX was originally a brand name used by the German company, Fotowerke Dr. C. Schleussner GmbH of Frankfurt am Main, the world's first photographic materials manufacturer. In 1962 the Schleussner family sold its photographic holdings to DuPont, an American company. DuPont used the brand for its subsidiary, Sterling Diagnostic Imaging for X-ray films. In 1999, Sterling was bought by the German company Agfa. Agfa did not use the brand and allowed its registration to lapse in 2003. Fotoimpex of Berlin, Germany, a company founded in 1992 to import photographic films and papers from former eastern Europe immediately registered the brand and today ADOX is a brand of black and white films, photographic papers and photochemistry produced by ADOX Fotowerke GmbH based in Bad Saarow near Berlin.

Fogging in photography is the deterioration in the quality of the image or the negative caused either by extraneous light, other electromagnetic radiation, radioactivity or the effects of a processing chemical. It is seen either as deposition of silver or dyes across all or part of the image unrelated to the original exposure. It can be confused with chemical staining that can be produced from poorly compounded developer, contamination of processing baths or poor washing after processing.

A chromogenic print, also known as a C-print or C-type print, a silver halide print, or a dye coupler print, is a photographic print made from a color negative, transparency or digital image, and developed using a chromogenic process. They are composed of three layers of gelatin, each containing an emulsion of silver halide, which is used as a light-sensitive material, and a different dye coupler of subtractive color which together, when developed, form a full-color image.

The following outline is provided as an overview of and topical guide to photography:

Sabatier or Sabattier can refer to:

<span class="mw-page-title-main">Photographic film</span> Film used by film (analog) cameras

Photographic film is a strip or sheet of transparent film base coated on one side with a gelatin emulsion containing microscopically small light-sensitive silver halide crystals. The sizes and other characteristics of the crystals determine the sensitivity, contrast, and resolution of the film. Film is typically segmented in frames, that give rise to separate photographs.

Photographic hypersensitization refers to a set of processes that can be applied to photographic film or plates before exposing. One or more of these processes is often needed to make photographic materials work better in long exposures.

<span class="mw-page-title-main">Solarization (photography)</span> Photographic tone reversal due to overexposure

In photography, solarization is the effect of tone reversal observed in cases of extreme overexposure of the photographic film in the camera. Most likely, the effect was first observed in scenery photographs including the sun. The sun, instead of being the whitest spot in the image, turned black or grey. For instance, Minor White's photograph of a winter scene, The Black Sun 1955, was a result of the shutter of his camera freezing in the open position, producing severe overexposure. Ansel Adams had also earlier created a solarized sun image, titled Black Sun, Owens Valley, California, 1939, by overexposure.

Equidensitometry is the technique of measuring equidensities in a photographic deposit or photographic layer, such as photographic films and photographic plates.

<span class="mw-page-title-main">Agfacontour Professional</span> Emulsion sheet film

Agfacontour Professional was a special emulsion sheet film which, after exposure and development in the Agfacontour developer, produced direct equidensities.

The solar camera, or solar enlarger, is an ancestor of the darkroom enlarger, and was used in the mid-to-late 19th century to make photographic enlargements from negatives.

References

  1. 1 2 Guyer, Jeff (24 September 2013). "The Sabattier Effect". Digital Photography School. Retrieved 2019-01-09.
  2. Spencer, D A (1973). The Focal Dictionary of Photographic Technologies. Focal Press. p. 539. ISBN   0-240-50747-9.
  3. Buffaloe, Ed. "Duo-tone Border Depletion Solarization (thiosulfate solarization)". Unblinkingeye.com. Retrieved 19 December 2015.
  4. "Sabattier Effect". The Focal Encyclopedia of Photography (Desk ed.). London: Focal Press Ltd. 1976. p. 1313.
  5. Spencer, D A (1973). The Focal Dictionary of Photographic Technologies. Focal Press. p. 248. ISBN   0-240-50747-9.
  6. Woodlief, Thomas Jr. (1973). The SPSE Handbook of Photographic Science and Engineering. John Wiley & Sons Inc. p. 428. ISBN   0-471-81880-1.
  7. Wijnekus, Franciskus J.M.; Wijnekus, E.F.P.H. (22 Oct 2013). Dictionary of the Printing and Allied Industries (2 ed.). Amsterdam: Elsevier Science Publishers B.V. p. 514. ISBN   978-0-44442-249-1. Sabattier effect
  8. American Journal of Photography and the Allied Arts and Science. New Series, New York II (1860), page 251
  9. "Bulletin de la Société française de photographie 1860" (in French). Hathi Trust Digital Library. 1860. pages 283 and 312
  10. "Bulletin de la Société française de photographie 1860" (in French). Hathi Trust Digital Library. 1860. page 306
  11. Woodlief, Thomas Jr. (1973). Carroll, Burt H. (ed.). SPSE Handbook of Photographic Science and Engineering. New York: John Wiley & Sons Inc. p. 428. ISBN   0471818801.
  12. 1 2 3 Tomamichel, Franz (1968). "8.5.3. Sabattiereffekt und Innenbildumkehr". In Frieser, Hellmut; Haase, Günter; Klein, Eberhard (eds.). Die photographische Empfindlichkeit. Vol. 3. Frankfurt am Main: Akademischer Verlagsgesellschaft. pp. 1200–1206. in German.{{cite book}}: |work= ignored (help)
  13. Bulletin Societé Francaise de Photographie 8 (1862), page 175, 289
  14. Le Moniteur de la Photographie 2 (1862), pages 27, 45, 50
  15. Junge, K.W. (1974). "1.8.1.9. Sabattiereffekt". In Teicher, Gerhard (ed.). Grundlagen der fotografischen Chemie (6 ed.). Leipzig: VEB Fotokinoverlag. pp. 76–77.{{cite book}}: |work= ignored (help)
  16. Applied Photography, Arnold et al., Focal Press, page 428
  17. US 6083671,Yurow, Harvey Warren,"Photographic developer for direct production of equidensity images on a high contrast film",published 1999-07-19,issued 2000-07-04
  18. Agfacontour Professional in der Photographik, Agfa-Gevaert AG Druckschrift Nr. 151 (in German)
  19. Agfacontour Professional in Wissenschaft und Technik, C. Sauer, Agfa-Gevaert AG Druckschrift nr. 152, 1. Auflage 1974 (in German)
  20. Yurow, Harvey W. "A Novel Approach to Equidensity Photographic Images". Unblinking Eye. Retrieved 28 February 2016.
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