Scientific assessment of hypoxia in U.S. coastal waters
The occurrence of hypoxia, or low dissolved oxygen, is increasing in coastal waters worldwide and represents a significant threat to the health and economy of our Nation’s coasts and Great Lakes. This trend is exemplified most dramatically off the coast of Louisiana and Texas, where the second largest eutrophication-related hypoxic zone in the world is associated with the nutrient pollutant load discharged by the Mississippi and Atchafalaya Rivers.Aquatic organisms require adequate dissolved oxygen to survive. The term “dead zone” is often used in reference to the absence of life (other than bacteria) from habitats that are devoid of oxygen. The inability to escape low oxygen areas makes immobile species, such as oysters and mussels, particularly vulnerable to hypoxia. These organisms can become stressed and may die due to hypoxia, resulting in significant impacts on marine food webs and the economy. Mobile organisms can flee the affected area when dissolved oxygen becomes too low. Nevertheless, fish kills can result from hypoxia, especially when the concentration of dissolved oxygen drops rapidly. New research is clarifying when hypoxia will cause fish kills asopposed to triggering avoidance behavior by fish. Further, new studies are better illustrating how habitat loss associated with hypoxia avoidance can impose ecological and economic costs, such as reduced growth in commercially harvested species and loss of biodiversity, habitat, and biomass. Transient or “diel-cycling” hypoxia, where conditions cycle from supersaturation of oxygen late in the afternoon to hypoxia or anoxia near dawn, most often occurs in shallow, eutrophic systems (e.g., nursery ground habitats) and may have pervasive impacts on living resources because of both its location and frequency of occurrence.
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| Format: | monograph biblioteca |
| Language: | English |
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Office of Science and Technology Policy/Council on Environmental Quality
2010-09
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| Subjects: | Ecology, Fisheries, Pollution, |
| Online Access: | http://hdl.handle.net/1834/30703 |
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dig-aquadocs-1834-307032021-06-26T05:28:44Z Scientific assessment of hypoxia in U.S. coastal waters Committee on Environment and Natural Resources Ecology Fisheries Pollution The occurrence of hypoxia, or low dissolved oxygen, is increasing in coastal waters worldwide and represents a significant threat to the health and economy of our Nation’s coasts and Great Lakes. This trend is exemplified most dramatically off the coast of Louisiana and Texas, where the second largest eutrophication-related hypoxic zone in the world is associated with the nutrient pollutant load discharged by the Mississippi and Atchafalaya Rivers.Aquatic organisms require adequate dissolved oxygen to survive. The term “dead zone” is often used in reference to the absence of life (other than bacteria) from habitats that are devoid of oxygen. The inability to escape low oxygen areas makes immobile species, such as oysters and mussels, particularly vulnerable to hypoxia. These organisms can become stressed and may die due to hypoxia, resulting in significant impacts on marine food webs and the economy. Mobile organisms can flee the affected area when dissolved oxygen becomes too low. Nevertheless, fish kills can result from hypoxia, especially when the concentration of dissolved oxygen drops rapidly. New research is clarifying when hypoxia will cause fish kills asopposed to triggering avoidance behavior by fish. Further, new studies are better illustrating how habitat loss associated with hypoxia avoidance can impose ecological and economic costs, such as reduced growth in commercially harvested species and loss of biodiversity, habitat, and biomass. Transient or “diel-cycling” hypoxia, where conditions cycle from supersaturation of oxygen late in the afternoon to hypoxia or anoxia near dawn, most often occurs in shallow, eutrophic systems (e.g., nursery ground habitats) and may have pervasive impacts on living resources because of both its location and frequency of occurrence. Interagency Working Group on Harmful Algal Blooms, Hypoxia, and Human Health 2021-06-24T16:57:03Z 2021-06-24T16:57:03Z 2010-09 monograph http://hdl.handle.net/1834/30703 en http://www.whitehouse.gov/sites/default/files/microsites/ostp/hypoxia-report.pdf http://www.cop.noaa.gov/stressors/extremeevents/hab/habhrca/hypoxiareportbrochure.pdf application/pdf application/pdf 154 Office of Science and Technology Policy/Council on Environmental Quality Washington, D.C. http://aquaticcommons.org/id/eprint/14833 403 2014-02-28 22:20:44 14833 |
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Ecology Fisheries Pollution Ecology Fisheries Pollution Scientific assessment of hypoxia in U.S. coastal waters |
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The occurrence of hypoxia, or low dissolved oxygen, is increasing in coastal waters worldwide and represents a significant threat to the health and economy of our Nation’s coasts and Great Lakes. This trend is exemplified most dramatically off the coast of Louisiana and Texas, where the second largest eutrophication-related hypoxic zone in the world is associated with the nutrient pollutant load discharged by the Mississippi and Atchafalaya Rivers.Aquatic organisms require adequate dissolved oxygen to survive. The term “dead zone” is often used in reference to the absence of life (other than bacteria) from habitats that are devoid of oxygen. The inability to escape low oxygen areas makes immobile species, such as oysters and mussels, particularly vulnerable to hypoxia. These organisms can become stressed and may die due to hypoxia, resulting in significant impacts on marine food webs and the economy. Mobile organisms can flee the affected area when dissolved oxygen becomes too low. Nevertheless, fish kills can result from hypoxia, especially when the concentration of dissolved oxygen drops rapidly. New research is clarifying when hypoxia will cause fish kills asopposed to triggering avoidance behavior by fish. Further, new studies are better illustrating how habitat loss associated with hypoxia avoidance can impose ecological and economic costs, such as reduced growth in commercially harvested species and loss of biodiversity, habitat, and biomass. Transient or “diel-cycling” hypoxia, where conditions cycle from supersaturation of oxygen late in the afternoon to hypoxia or anoxia near dawn, most often occurs in shallow, eutrophic systems (e.g., nursery ground habitats) and may have pervasive impacts on living resources because of both its location and frequency of occurrence. |
| author2 |
Committee on Environment and Natural Resources |
| author_facet |
Committee on Environment and Natural Resources |
| format |
monograph |
| topic_facet |
Ecology Fisheries Pollution |
| title |
Scientific assessment of hypoxia in U.S. coastal waters |
| title_short |
Scientific assessment of hypoxia in U.S. coastal waters |
| title_full |
Scientific assessment of hypoxia in U.S. coastal waters |
| title_fullStr |
Scientific assessment of hypoxia in U.S. coastal waters |
| title_full_unstemmed |
Scientific assessment of hypoxia in U.S. coastal waters |
| title_sort |
scientific assessment of hypoxia in u.s. coastal waters |
| publisher |
Office of Science and Technology Policy/Council on Environmental Quality |
| publishDate |
2010-09 |
| url |
http://hdl.handle.net/1834/30703 |
| _version_ |
1756078728393261056 |