Difference between revisions of "Pollutant"
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== Description == | == Description == | ||
− | An [[aerosol|aerosol]], or [[particulate|particulate]] contaminant. Pollutants are generated by natural and man-made sources, such as decomposition, abrasion, or combustion. Pollutants may be damaging or toxic to the environment, people, and materials. Currently the pollutants with the highest outdoor concentrations generally occur in big cities ([[nitrogen%20oxides|nitrogen oxides]], [[hydrocarbon|hydrocarbons]], [[ozone|ozone]], [[carbon%20monoxide|carbon monoxide]], [[particulate|particulates]]) or near smoke stacks ([[sulfur%20dioxide|sulfur dioxide]], nitrogen oxides). Very dense | + | An [[aerosol|aerosol]], or [[particulate|particulate]] contaminant. Pollutants are generated by natural and man-made sources, such as decomposition, abrasion, or combustion. Pollutants may be damaging or toxic to the environment, people, and materials. Currently the pollutants with the highest outdoor concentrations generally occur in big cities ([[nitrogen%20oxides|nitrogen oxides]], [[hydrocarbon|hydrocarbons]], [[ozone|ozone]], [[carbon%20monoxide|carbon monoxide]], [[particulate|particulates]]) or near smoke stacks ([[sulfur%20dioxide|sulfur dioxide]], nitrogen oxides). Very dense [[haze|haze]], or combination of smoke and fog, is called smog. Indoor air pollutants ([[organic%20acid|organic acids]], [[aldehyde|aldehydes]], hydrocarbons, ozone, particulates, etc) are emitted from construction materials (wood, insulation, carpets, paints), office machines (copiers, printers) or are transported inside from the outdoor environment. Once inside a museum, pollutants can deposit and interact deleteriously with museum materials. The concentration of air pollutants may be decreased by minimizing sources or by reacting or absorbing the pollutants from the air. [[Scavenger|Scavengers]] provide one method to minimize the concentration of air pollutants in contained spaces. |
+ | Comparison table of aerosol pollutants information from Canosa and Norrehed (2019) and Jean Tétreault (2011). | ||
{| class="wikitable" | {| class="wikitable" | ||
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! Collection Risks | ! Collection Risks | ||
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− | | | + | | Acetaldehyde; acetic acid |
− | | Fuel combustion, | + | | Fuel combustion; wood (especially oak, cedar, etc.) and wood products, biological processes, PVC flooring, laminated materials, paints, adhesives, sealants, tobacco smoke, cellulose acetate decomposition; acetaldehyde is a precursor of acetic acid |
− | | Metal corrosion, | + | | Metal corrosion, reaction with calcareous materials, cellulose and protein embrittlement, degradation of soda-rich glass, enamels, and pigments; acidification of paper |
+ | |- | ||
+ | | Formaldehyde; formic acid | ||
+ | | Fuel combustion, wood and wood products, resins, oil-based paints, natural history specimens, fiberglass, photocopiers, textiles, construction materials, PVC carpeting, laminates, tobacco smoke, gas ovens, adhesives, sealants; formaldehyde is a precursor of formic acid | ||
+ | | Metal corrosion, reaction with calcareous materials, cellulose and, protein embrittlement, discoloration of dyes, pigments, and textiles; acidification of paper | ||
+ | |- | ||
+ | | Ammonia | ||
+ | | Latex paints, cleaning products, food preparation, HVAC systems, people, concrete, biomaterial degradation, fertilizers | ||
+ | | Crystal growth on cellulose nitrate objects, yellowing of linseed oil; corrosion of copper alloys | ||
|- | |- | ||
| Ozone | | Ozone | ||
| Smog, photocopiers, laser printers, electrostatic particle filters; UV light sources, arc welders | | Smog, photocopiers, laser printers, electrostatic particle filters; UV light sources, arc welders | ||
| Rubber, cellulose and protein embrittlement, dye, ink and pigment discoloration, photograph and book deterioration | | Rubber, cellulose and protein embrittlement, dye, ink and pigment discoloration, photograph and book deterioration | ||
+ | |- | ||
+ | | Peroxides | ||
+ | | Secondary product from polymerization of alkyds, drying oil, urethanes, epoxies such as found in some adhesives and paints | ||
+ | | Cellulose degradation, black spotting on photographs, oxidation of proteins (leather and wool), discoloration or bleaching | ||
|- | |- | ||
| Nitrogen oxides; nitric acid | | Nitrogen oxides; nitric acid | ||
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| Cellulose and protein embrittlement, dye, ink and pigment discoloration, photographic film deterioration | | Cellulose and protein embrittlement, dye, ink and pigment discoloration, photographic film deterioration | ||
|- | |- | ||
+ | | Sulfur dioxide; sulfuric acid | ||
+ | | Fuel combustion, pulp and paper production, biological activity, pyrite oxidation, vulcanized rubber, proteinaceous materials inside enclosures | ||
+ | | Metal corrosion, dye fading, cellulose embrittlement, photograph deterioration, leather red-rot, pigment darkening, reaction with calcareous materials | ||
+ | |- | ||
| Sulfides; hydrogen sulfide | | Sulfides; hydrogen sulfide | ||
| Fuel combustion, humans, natural gas, marshes, volcanoes, wool, silk, felt, furs, vulcanized rubber, waterlogged archaeological organic materials, pyrite collections | | Fuel combustion, humans, natural gas, marshes, volcanoes, wool, silk, felt, furs, vulcanized rubber, waterlogged archaeological organic materials, pyrite collections | ||
| Metal corrosion, photograph silver mirroring and redox spots, leather red-rot, lead pigment darkening, stone deterioration; paper and fabric discoloration | | Metal corrosion, photograph silver mirroring and redox spots, leather red-rot, lead pigment darkening, stone deterioration; paper and fabric discoloration | ||
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| Particulates | | Particulates | ||
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==Resources and Citations== | ==Resources and Citations== | ||
+ | * Jean Tétreault, "Sustainable Use of Coatings in Museums and Archives" Canadian Conservation Institute, 2011 [ https://www.morana-rtd.com/e-preservationscience/2011/Tetreault-05-01-2011.pdf Link] | ||
* AIC Conservation Wiki: [https://www.conservation-wiki.com/wiki/Category:Exhibit_Technical_Notes Exhibit Technical Notes: Environmental Control] | * AIC Conservation Wiki: [https://www.conservation-wiki.com/wiki/Category:Exhibit_Technical_Notes Exhibit Technical Notes: Environmental Control] | ||
* Exhibit Guidelines Technical Note: [https://www.conservation-wiki.com/wiki/Monitoring_Pollutants_Inside_an_Exhibit_Case Monitoring Pollutants Inside an Exhibit Case] | * Exhibit Guidelines Technical Note: [https://www.conservation-wiki.com/wiki/Monitoring_Pollutants_Inside_an_Exhibit_Case Monitoring Pollutants Inside an Exhibit Case] | ||
* Exhibit Guidelines Technical Note: [https://www.conservation-wiki.com/wiki/Using_Pollutant_Absorbers_Inside_an_Exhibit_Case Using Pollutant Absorbers Inside an Exhibit Case] | * Exhibit Guidelines Technical Note: [https://www.conservation-wiki.com/wiki/Using_Pollutant_Absorbers_Inside_an_Exhibit_Case Using Pollutant Absorbers Inside an Exhibit Case] | ||
* Jean Tétreault, Airborne Pollutants in Museums, Galleries and Archives: Risk Assessment, Control Strategies and Preservation Management. Ottawa, Canada: Canadian Conservation Institute, 2003. | * Jean Tétreault, Airborne Pollutants in Museums, Galleries and Archives: Risk Assessment, Control Strategies and Preservation Management. Ottawa, Canada: Canadian Conservation Institute, 2003. | ||
− | * Cecily Grzywacz, Tools for Conservation: Monitoring for Gaseous Pollutants in Museum Environments. Los Angeles: Getty Publications. 2006. | + | * Cecily Grzywacz, Tools for Conservation: [https://www.getty.edu/publications/virtuallibrary/0892368519.html Monitoring for Gaseous Pollutants in Museum Environments]. Los Angeles: Getty Publications. 2006. |
* Elyse Canosa & Sara Norrehed; Strategies for Pollutant Monitoring in Museum Environments, Swedish National Heritage Board, 2019. [https://www.diva-portal.org/smash/get/diva2:1324224/FULLTEXT01.pdf Link] | * Elyse Canosa & Sara Norrehed; Strategies for Pollutant Monitoring in Museum Environments, Swedish National Heritage Board, 2019. [https://www.diva-portal.org/smash/get/diva2:1324224/FULLTEXT01.pdf Link] | ||
* Jean Tétreault, Agent of Deterioration: Pollutants [https://www.canada.ca/en/conservation-institute/services/agents-deterioration/pollutants.html#pollu2 Airborne Pollutants] | * Jean Tétreault, Agent of Deterioration: Pollutants [https://www.canada.ca/en/conservation-institute/services/agents-deterioration/pollutants.html#pollu2 Airborne Pollutants] | ||
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− | [[Category:Materials database]][[Category: MWG]][[Category: Climate/Environment]] | + | [[Category:Materials database]][[Category: MWG]][[Category: Climate/Environment]][[Category: Comparisons]] |
Latest revision as of 08:42, 9 October 2024
Description
An Aerosol, or Particulate contaminant. Pollutants are generated by natural and man-made sources, such as decomposition, abrasion, or combustion. Pollutants may be damaging or toxic to the environment, people, and materials. Currently the pollutants with the highest outdoor concentrations generally occur in big cities (Nitrogen oxides, hydrocarbons, Ozone, Carbon monoxide, particulates) or near smoke stacks (Sulfur dioxide, nitrogen oxides). Very dense Haze, or combination of smoke and fog, is called smog. Indoor air pollutants (organic acids, aldehydes, hydrocarbons, ozone, particulates, etc) are emitted from construction materials (wood, insulation, carpets, paints), office machines (copiers, printers) or are transported inside from the outdoor environment. Once inside a museum, pollutants can deposit and interact deleteriously with museum materials. The concentration of air pollutants may be decreased by minimizing sources or by reacting or absorbing the pollutants from the air. Scavengers provide one method to minimize the concentration of air pollutants in contained spaces.
Comparison table of aerosol pollutants information from Canosa and Norrehed (2019) and Jean Tétreault (2011).
Pollutant | Sources | Collection Risks |
---|---|---|
Acetaldehyde; acetic acid | Fuel combustion; wood (especially oak, cedar, etc.) and wood products, biological processes, PVC flooring, laminated materials, paints, adhesives, sealants, tobacco smoke, cellulose acetate decomposition; acetaldehyde is a precursor of acetic acid | Metal corrosion, reaction with calcareous materials, cellulose and protein embrittlement, degradation of soda-rich glass, enamels, and pigments; acidification of paper |
Formaldehyde; formic acid | Fuel combustion, wood and wood products, resins, oil-based paints, natural history specimens, fiberglass, photocopiers, textiles, construction materials, PVC carpeting, laminates, tobacco smoke, gas ovens, adhesives, sealants; formaldehyde is a precursor of formic acid | Metal corrosion, reaction with calcareous materials, cellulose and, protein embrittlement, discoloration of dyes, pigments, and textiles; acidification of paper |
Ammonia | Latex paints, cleaning products, food preparation, HVAC systems, people, concrete, biomaterial degradation, fertilizers | Crystal growth on cellulose nitrate objects, yellowing of linseed oil; corrosion of copper alloys |
Ozone | Smog, photocopiers, laser printers, electrostatic particle filters; UV light sources, arc welders | Rubber, cellulose and protein embrittlement, dye, ink and pigment discoloration, photograph and book deterioration |
Peroxides | Secondary product from polymerization of alkyds, drying oil, urethanes, epoxies such as found in some adhesives and paints | Cellulose degradation, black spotting on photographs, oxidation of proteins (leather and wool), discoloration or bleaching |
Nitrogen oxides; nitric acid | Biological processes, fuel combustion, cellulose nitrate decomposition, tobacco smoke, photocopiers | Cellulose and protein embrittlement, dye, ink and pigment discoloration, photographic film deterioration |
Sulfur dioxide; sulfuric acid | Fuel combustion, pulp and paper production, biological activity, pyrite oxidation, vulcanized rubber, proteinaceous materials inside enclosures | Metal corrosion, dye fading, cellulose embrittlement, photograph deterioration, leather red-rot, pigment darkening, reaction with calcareous materials |
Sulfides; hydrogen sulfide | Fuel combustion, humans, natural gas, marshes, volcanoes, wool, silk, felt, furs, vulcanized rubber, waterlogged archaeological organic materials, pyrite collections | Metal corrosion, photograph silver mirroring and redox spots, leather red-rot, lead pigment darkening, stone deterioration; paper and fabric discoloration |
Particulates | Combustion residues (soot, smog, smoke, flyash), construction (roads, buildings, vehicles), humans (proteins), fibers (lint), biological specimens (spores, pollen), soil (dust, salt) | Some objects are difficult to clean (feathers, minerals, microcracks, sticky objects, etc.); Dust can cause disfiguration of objects, attract pests, and scratch soft surfaces by friction. |
Water vapor | Water vapor from visitors, water-based paints, and adhesives, wet cleaning activities and outdoor environment; | Can produce both physical and chemical deterioration; fluctuations can damage wood products; hydrolysis of cellulosic materials including cellulose acetate and cellulose nitrate; objects with salts, gelatin, natural varnish are susceptible; causes oxides to convert to acids |
Synonyms and Related Terms
pollutants; air pollutants; pollution
Resources and Citations
- Jean Tétreault, "Sustainable Use of Coatings in Museums and Archives" Canadian Conservation Institute, 2011 [ https://www.morana-rtd.com/e-preservationscience/2011/Tetreault-05-01-2011.pdf Link]
- AIC Conservation Wiki: Exhibit Technical Notes: Environmental Control
- Exhibit Guidelines Technical Note: Monitoring Pollutants Inside an Exhibit Case
- Exhibit Guidelines Technical Note: Using Pollutant Absorbers Inside an Exhibit Case
- Jean Tétreault, Airborne Pollutants in Museums, Galleries and Archives: Risk Assessment, Control Strategies and Preservation Management. Ottawa, Canada: Canadian Conservation Institute, 2003.
- Cecily Grzywacz, Tools for Conservation: Monitoring for Gaseous Pollutants in Museum Environments. Los Angeles: Getty Publications. 2006.
- Elyse Canosa & Sara Norrehed; Strategies for Pollutant Monitoring in Museum Environments, Swedish National Heritage Board, 2019. Link
- Jean Tétreault, Agent of Deterioration: Pollutants Airborne Pollutants
- Pam Hatchfield, Pollutants in the Museum Environment, Archetype Press, London, 2002
- A Glossary of Paper Conservation Terms, Margaret Ellis (ed.), Conservation Center of the Institute of Fine Arts, New York City, 1998
- Art and Architecture Thesaurus Online, https://www.getty.edu/research/tools/vocabulary/aat/, J. Paul Getty Trust, Los Angeles, 2000
- Website: AMOL reCollections Glossary -http://amol.org.au/recollections/7/p/htm