- Cellulose acetate film
Cellulose acetate film, or safety film, is used in photography as a base material for photographic emulsions. It was introduced in the early 20th century by film manufacturers as a safe film base replacement for unstable and highly flammable nitrate film.
Beginning with cellulose diacetate in 1909, this innovation continued with cellulose acetate propionate and cellulose acetate butyrate in the 1930s, and finally in the late 1940s, cellulose triacetate was introduced, alongside polyester bases. These less flammable substitutes for nitrate film were called safety film.
The motion picture industry continued to use cellulose nitrate supports until the introduction of cellulose triacetate in 1948, which met the rigorous safety and performance standards set by the cinematographic industry. The chemical instability of this material, unrecognized at the time of its introduction, has since become a major threat for film collections.
Decay and the "vinegar syndrome"
The first instance of cellulose triacetate degradation was reported to the Eastman Kodak Company within a decade of its introduction in 1948. The first report came from the Government of India, whose film was stored in hot, humid conditions. It was followed by further reports of degradation from collections stored in similar conditions. These observations resulted in continuing studies in the Kodak laboratories during the 1960s.
Beginning in the 1980s, there was a great deal of focus upon film stability following frequent reports of cellulose triacetate degradation. This material releases acetic acid, the key ingredient in vinegar and responsible for its acidic smell. The problem became known as the "vinegar syndrome."
The progression of degradation
In acetate film, acetyl (CH3CO) groups are attached to long molecular chains of cellulose. With exposure to moisture, heat, or acids, these acetyl groups break from their molecular bonds and acetic acid is released. While the acid is initially released inside the plastic, it gradually diffuses to the surface, causing a characteristic vinegary smell.
The decay process follows this pattern:
- Acetic acid is released during the initial acetate base deterioration, leading to the characteristic vinegar odor. This signal marks the progression of deterioration.
- The plastic film base becomes brittle. This occurs in the advanced stages of deterioration, weakening the film and causing it to shatter with the slightest tension. These physical changes happen because cellulose acetate consists of long chains of repeating units, or polymers. When the acetic acid is released as these groups break off, the acidic environment helps to break the links between units, shortening the polymer chains and leading to brittleness.
- Shrinkage also occurs during this process. With the cellulose acetate polymer chains breaking into smaller pieces, and with their side groups splitting off, the plastic film begins to shrink. In advanced stages of deterioration, shrinkage can be as much as 10%. A 1% reduction in size renders motion picture film unusable.
- As the acetate base shrinks, the gelatin emulsion of the film does not shrink, because it is not undergoing deterioration. The emulsion and film base separate, causing buckling, referred to by archivists as 'channelling.' Sheet films are often severely channelled in the later stages of degradation.
- Crystalline deposits or liquid-filled bubbles appear on the emulsion. These are evidence of plasticizers, additives to the plastic base, becoming incompatible with the film base and oozing out on the surface. This discharge of plasticizers is a sign of advanced degradation.
- In some cases, pink or blue colors appear in some sheet films. This is caused by antihalation dyes, which are normally colorless and incorporated into the gelatin layer. When acetic acid is formed during deterioration, the acidic environment causes the dyes to return to their original pink or blue color.
Testing for degradation
A testing product developed by the Image Permanence Institute, A-D, or "acid-detection" indicator strips change color from blue through shades of green to yellow with increasing exposure to acid. According to the test User's Guide, they were "...created to aid in the preservation of collections of photographic film, including sheet and roll films, cinema film, and microfilm. They provide a nondestructive method of determining the extent of vinegar syndrome in film collections."  These tools can be used to determine the extent of damage to a film collection and which steps should be taken to prolong their usability.
Preservation and storage
Currently there is no practical way of halting or reversing the course of degradation. While there has been significant research regarding various methods of slowing degradation, such as storage in molecular sieves, temperature and moisture are the two key factors affecting the rate of deterioration. According to the Image Permanence Institute, fresh acetate film stored at a temperature of 65°F (18°C) and 50% relative humidity will last approximately 50 years before the onset of vinegar syndrome. Reducing the temperature 15°, while maintaining the same level of humidity, delays the process by 150 years. A combination of low temperature and low relative humidity represents the optimum storage condition for cellulose acetate base films, however, in practice temperatures of 55°F (12°C) and a relative humidity of 35% are now being used.
Microenvironments—the conditions inside an enclosure—can also have an impact on the condition of cellulose acetate film. Enclosures that are breathable or that contain an acid absorbent are instrumental in reducing the rate of decay due to vinegar syndrome. Sealed metal containers can trap the decay products released by the film, promoting the spread of vinegar syndrome.
Rescuing damaged film
During early stages of decay, the film content can be rescued by transferring it to new film stock. Once the film becomes brittle it cannot be copied in its entirety. Because the gelatin emulsion usually stays intact during the degradation process, it is possible to save the image on sheet film using solvents to dissolve the emulsion away from the shrunken base. Once the emulsion has been freed from the shrunken support, it can be photographed or transferred to a new support. Because of the solvents used, this is a delicate and potentially hazardous procedure and is an expensive process for a large collection. Degraded motion picture film cannot be restored in this way, but sheet films often can.
While digitization would be an ideal way to preserve the contents of cellulose acetate film, current standards do not allow for scanning at sufficient resolutions to produce a copy of the same picture and sound quality as the original. Currently, the National Film Preservation Institute advocates film-to-film transfer as the best method for film preservation, with the copies stored in proper environmental conditions.
Cellulose acetate film is also used to make replicates of materials and biological samples for microscopy. The techniques were developed for metallographic needs to examine the grain structure of polished metals. Replication can be used to understand the distribution, for example, of different types of iron in carbon steel samples, or the fine distribution of damage to a sample subject to mechanical wear.
- ^ National Film Preservation Foundation. The Film Preservation Guide: The Basics for Archives, Libraries, and Museums. San Francisco: National Film Preservation Foundation, 2004, 9.
- ^ Ram, A. Tulsi. “Archival Preservation of Photographic Film-A Perspective.” Polymer Degradation and Stability 29 (1990), 4.
- ^ Adelstein, P.Z., J.M. Reilly, D.W. Nishimura, and C.J. Erbland. "Stability of Cellulose Ester Base Photographic Film: Part I-Laboratory Testing Procedures." SMPTE Journal 101 no.5 (1992): 336.
- ^ James M. Reilly. "Basic Strategy for Acetate Film Preservation." Microform and Imaging Review 31 no.4 (2002), 117.
- ^ Image Permanence Institute. User's Guide for A-D Strips: Film Base Deterioration Monitor. Rochester: Image Permanence Institute, 2001.
- ^ Allen, N.S., M. Edge, C.V. Horie, T.S. Jewitt, and J.H. Appleyard. “Degradation of Historic Cellulose Triacetate Cinematograph Film: Influence of Various Film Parameters and Prediction of Archival Life.” The Journal of Photographic Science 36 no. 6 (1998), 194.
- ^ Reilly, James M. IPI Storage Guide for Acetate Film; Instructions of Using the Wheel, Graphs, and Table; Basic Strategy for Film Preservation. Rochester: Image Permanence Institute, 1993.
- ^ Adelstein, P.Z., J.M. Reilly, D.W. Nishimura, and C.J. Erbland. “Stability of Cellulose Ester Base Photographic Film: Part II-Practical Storage Considerations.” SMPTE Journal 101 no. 5 (May 1992): 353.
- ^ "Film and Media Storage". http://www.bonded.com/storage.php.
- ^ J.L. Bigourdan and J. Reilly, “Effectiveness of Storage Conditions in Controlling the Vinegar Syndrome: Preservation Strategies for Acetate Base Motion-Picture Film Collections”, Image Permanence Institute, Rochester Institute of Technology.
- ^ Reilly, James M. “Basic Strategy for Acetate Film Preservation.” Microform and Imaging Review 31 no. 4 (2002): 118.
- ^ www.filmpreservation.org/preservation/film_guide.html
- ^ [http://www.sciencedirect.com/science/article/pii/0026080084900028 Measurement of the interlamellar spacing of pearlite ]
- ^ Mechanisms of wear of the metal surface during fretting corrosion of steel on polymers
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- Adelstein, P.Z., J.M. Reilly, D.W. Nishimura, and C.J. Erbland. “Stability of Cellulose Ester Base Photographic Film: Part II-Practical Storage Considerations.” SMPTE Journal 101 no. 5 (May 1992): 347-354.
- Adelstein, P.Z., J.M. Reilly, D.W. Nishimura, and C.J. Erbland. “Stability of Cellulose Ester Base Photographic Film: Part III-Measurement of Film Degradation.” SMPTE Journal 104 (May 1995): 281-291.
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- Allen, N.S., M. Edge, C.V. Horie, T.S. Jewitt, and J.H. Appleyard. “The Degradation Characteristics of Archival Cellulose Triacetate Base Cinematograph Film.” The Journal of Photographic Science 36 no. 6 (1998), 199-203.
- Allen, N.S., M. Edge, T.S. Jewitt, and C.V. Horie. “Initiation of the Degradation of Cellulose Triacetate Base Motion Picture Film.” The Journal of Photographic Science 38 no. 2 (1990): 54-59.
- Allen, N.S., J.H. Appleyard, E. Edge, D. Francis, C.V. Horie, and T.S. Jewitt. “The Nature of the Degradation of Archival Cellulose-Ester Base Motion-Picture Film: The Case for Stabilization.” The Journal of Photographic Science 36 no.2 (1988): 34-39.
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- Bigourdan, Jean-Louis and James M. Reilly. “Effectiveness of storage Conditions in Controlling the Vinegar syndrome: Preservation Strategies for Acetate Base Motion-Picture Film Collections.” In Michelle Aubert and Richard Billeaud. Archiver et communiquer l'image et le son :les enjeux du 3ème millenaire : actes du Symposium Technique Mixte—JTS Paris 2000, 14-43. Paris: CNC, 2000.
- Edge, M. and N.S. Allen. “Fundamental Aspects of the Degradation of Cellulose Triacetate Base Cinematograph Film.” Polymer Degradation and Stability 25 no. 2-4 (1989): 345-362.
- Horvath, David G. (1987). The Acetate Negative Survey Final Report. Louisville, KY: Ekstrom Library Photographic Archives, University of Louisville. 
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- Reilly, James M. “Basic Strategy for Acetate Film Preservation.” Microform and Imaging Review 31 no. 4 (2002): 117-130.
- Reilly, James M. IPI Storage Guide for Acetate Film; Instructions of Using the Wheel, Graphs, and Table; Basic Strategy for Film Preservation. Rochester: Image Permanence Institute, 1993.
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