Benthic shear stress and sediment condition

This article presents a literature review and analysis which finds that the conditions in a shallow waterway are dependent on the underlying shear stress. Circulation and mixing have been recognised as somehow important to the health of the lower water column and sediment of a pond. Benthic shear st...

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Published in	Aquacultural engineering Vol. 21; no. 2; pp. 85 - 111
Main Author	Peterson, Eric L.
Format	Journal Article
Language	English
Published	Amsterdam Elsevier B.V 01.12.1999 Elsevier Science
Subjects	anaerobic conditions Animal aquaculture Animal productions benthic organisms biochemical oxygen demand Biological and medical sciences Brackish Freshwater Fundamental and applied biological sciences. Psychology General aspects habitats Marine mathematical models organic matter oxygen consumption particle size Pond circulation ponds Sediment condition Sediment oxygen demand silt water flow waterways Pond circulation Sediment condition Sediment oxygen demand Breeding pond Oxygen Shear stress Review Sediments Aquaculture Benthic zone
Online Access	Get full text
ISSN	0144-8609 1873-5614
DOI	10.1016/S0144-8609(99)00025-4

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Abstract	This article presents a literature review and analysis which finds that the conditions in a shallow waterway are dependent on the underlying shear stress. Circulation and mixing have been recognised as somehow important to the health of the lower water column and sediment of a pond. Benthic shear stress is identified as one of the principal governors of sediment condition. Benthic shear stress regulates the convection of volatile substances such as oxygen across the sediment–water interface. Benthic shear stress is the primary determinant of where particulate matter scours, rolls, saltates, settles, and consolidates. The critical shear stress of very small particles tends to be determined by density rather than size. Excessive shear stress may cause organic material to become buried under a fallout of silt in locations with lower shear stress. Such organic matter trapped in a sludge blanket consumes oxygen faster than it can diffuse through the pores between grains of soil, resulting in anaerobic soils. The objective of pond aeration and circulation systems should be to optimise conditions for the growth of cultured stock. Better management of the epi-benthic habitat of shrimp and prawns would concurrently reduce the use of energy and soil. The finding is that pond sediment condition may be assessed in terms of benthic shear stress. Control of benthic shear stress would enable resuspension and oxygenation of organic detritus without making the situation worse by intermixing organic matter with mineral soil. Desirable benthic shear stresses are expected to exist in the range of 0.003–0.03 N/m 2 where organic matter is gently maintained in an aerobic state. Locations having less than 0.001 N/m 2 benthic shear stress are subject to burial under accumulating mineral silts. Excessive scour occurs in locations having more than 0.1 N/m 2. High stress locations are the source of suspended solids which fallout on locations experiencing lower rates of benthic shear stress. The declining productivity of shrimp mariculture ponds is associated with excessive stocking and feeding because these practices necessitate intensive aeration, which results in high rates of pond circulation. The circulation causes soil to be scoured in some places while fallout covers the bottom in other places. Consequently intensive cropping of a pond causes feed pellets and other organic material to be buried in the soil, creating anaerobic conditions whereby bacterial metabolites are produced and released into the water column.
AbstractList	This article presents a literature review and analysis which finds that the conditions in a shallow waterway are dependent on the underlying shear stress. Circulation and mixing have been recognised as somehow important to the health of the lower water column and sediment of a pond. Benthic shear stress is identified as one of the principal governors of sediment condition. Benthic shear stress regulates the convection of volatile substances such as oxygen across the sediment–water interface. Benthic shear stress is the primary determinant of where particulate matter scours, rolls, saltates, settles, and consolidates. The critical shear stress of very small particles tends to be determined by density rather than size. Excessive shear stress may cause organic material to become buried under a fallout of silt in locations with lower shear stress. Such organic matter trapped in a sludge blanket consumes oxygen faster than it can diffuse through the pores between grains of soil, resulting in anaerobic soils. The objective of pond aeration and circulation systems should be to optimise conditions for the growth of cultured stock. Better management of the epi-benthic habitat of shrimp and prawns would concurrently reduce the use of energy and soil. The finding is that pond sediment condition may be assessed in terms of benthic shear stress. Control of benthic shear stress would enable resuspension and oxygenation of organic detritus without making the situation worse by intermixing organic matter with mineral soil. Desirable benthic shear stresses are expected to exist in the range of 0.003–0.03 N/m 2 where organic matter is gently maintained in an aerobic state. Locations having less than 0.001 N/m 2 benthic shear stress are subject to burial under accumulating mineral silts. Excessive scour occurs in locations having more than 0.1 N/m 2. High stress locations are the source of suspended solids which fallout on locations experiencing lower rates of benthic shear stress. The declining productivity of shrimp mariculture ponds is associated with excessive stocking and feeding because these practices necessitate intensive aeration, which results in high rates of pond circulation. The circulation causes soil to be scoured in some places while fallout covers the bottom in other places. Consequently intensive cropping of a pond causes feed pellets and other organic material to be buried in the soil, creating anaerobic conditions whereby bacterial metabolites are produced and released into the water column. This article presents a literature review and analysis which finds that the conditions in a shallow waterway are dependent on the underlying shear stress. Circulation and mixing have been recognised as somehow important to the health of the lower water column and sediment of a pond. Benthic shear stress is identified as one of the principal governors of sediment condition. Benthic shear stress regulates the convection of volatile substances such as oxygen across the sediment-water interface. Benthic shear stress is the primary determinant of where particulate matter scours, rolls, saltates, settles, and consolidates. The critical shear stress of very small particles tends to be determined by density rather than size. Excessive shear stress may cause organic material to become buried under a fallout of silt in locations with lower shear stress. Such organic matter trapped in a sludge blanket consumes oxygen faster than it can diffuse through the pores between grains of soil, resulting in anaerobic soils. The objective of pond aeration and circulation systems should be to optimise conditions for the growth of cultured stock. Better management of the epi-benthic habitat of shrimp and prawn would concurrently reduce the use of energy and soil. The finding is that pond sediment condition may be assessed in terms of benthic shear stress. Control of benthic shear stress would enable resuspension and oxygenation of organic detritus without making the situation worse by intermixing organic matter with mineral soil. Desirable benthic shear stresses are expected to exist in the range of 0.003-0.03 N/m super(2) where organic matter is gently maintained in an aerobic state. Locations having less than 0.001 N/m super(2) benthic shear stress are subject to burial under accumulating mineral silts. Excessive scour occurs in locations having more than 0.1 N /m super(2). High stress locations are the source of suspended solids which fallout on locations experiencing lower rates of benthic shear stress. The declining productivity of shrimp mariculture ponds is associated with excessive stocking and feeding because these practices necessitate intensive aeration, which results in high rates of pond circulation. The circulation causes soil to be scoured in some places while fallout covers the bottom in other places. Consequently intensive cropping of a pond causes feed pellets and other organic material to be buried in in the soil, creating anaerobic conditions whereby bacterial metabolites are produced and released into the water column.
Author	Peterson, Eric L.
Author_xml	– sequence: 1 givenname: Eric L. surname: Peterson fullname: Peterson, Eric L. email: eric.peterson@jcu.edu.au organization: School of Engineering and the Cooperative Research Centre for Aquaculture, James Cook University, Townsville 4811, Australia
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Cites_doi	10.4319/lo.1990.35.6.1343 10.1098/rsta.1895.0004 10.1111/j.1749-7345.1980.tb00102.x 10.1016/0144-8609(89)90041-1 10.1111/j.1365-3091.1977.tb00136.x 10.1002/aic.690230106 10.1016/S0044-8486(96)01487-1 10.1016/S0924-7963(96)00130-3 10.1016/S0144-8609(99)00025-4 10.1016/S0924-7963(96)00127-3 10.1016/0144-8609(91)90016-D 10.1016/S0044-8486(96)01361-0 10.1016/0967-0645(95)00013-G 10.1016/0144-8609(82)90038-3 10.1071/MF9950295 10.1007/BF00005731 10.1111/j.1365-2109.1998.tb01110.x
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Keywords	Pond circulation Sediment condition Sediment oxygen demand Breeding pond Oxygen Shear stress Review Sediments Aquaculture Benthic zone
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Snippet	This article presents a literature review and analysis which finds that the conditions in a shallow waterway are dependent on the underlying shear stress....
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SubjectTerms	anaerobic conditions Animal aquaculture Animal productions benthic organisms biochemical oxygen demand Biological and medical sciences Brackish Freshwater Fundamental and applied biological sciences. Psychology General aspects habitats Marine mathematical models organic matter oxygen consumption particle size Pond circulation ponds Sediment condition Sediment oxygen demand silt water flow waterways
Title	Benthic shear stress and sediment condition
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