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Riffle

January 10, 2024

For other uses, see Riffle (disambiguation).

A riffle is a shallow landform in a flowing channel.[1] Colloquially, it is a shallow place in a river where water flows quickly past rocks.[2] However, in geology a riffle has specific characteristics.

Riffle on the Onega River

Topographic, sedimentary and hydraulic indicators edit

Riffles are almost always found to have a very low discharge compared to the flow that fills the channel[3] (approximately 10–20%), and as a result the water moving over a riffle appears shallow and fast, with a wavy, disturbed water surface. The water's surface over a riffle at low flow also has a much steeper slope than that over other in-channel landforms. Channel sections with a mean water surface slope of roughly 0.1 to 0.5% exhibit riffles, though they can occur in steeper or gentler sloping channels with coarser or finer bed materials, respectively. Except in the period after a flood (when fresh material is deposited on a riffle), the sediment on the riverbed in a riffle is usually much coarser than on that in any other in-channel landform.

Terrestrial valleys normally consist of channels – geometric depressions in the valley floor carved by flowing water – and overbank regions that include floodplains and terraces. Some channels have shapes and sizes that hardly change along the river; these do not have riffles. However, many channels exhibit readily apparent changes in width, bed elevation, and slope. In these cases, scientists realized that the riverbed often tends to rise and fall with distance downstream relative to an average elevation of the river's slope. That led scientists to map the bed elevation down the deepest path in a channel, called the thalweg, to obtain a longitudinal profile. Then, the piecewise linear slope of the river is computed and removed to leave just the rise and fall of the elevation about the channel's trendline. According to the zero-crossing method,[4][5] riffles are all the locations along the channel whose residual elevation is greater than zero. Because of the prevalence of this method for identifying and mapping riffles, riffles are often thought of as part of a paired sequence, alternating with pools (the lows between the riffles). However, modern topographic maps of rivers with meter-scale resolution reveal that rivers exhibit a diversity of in-channel landforms.[6]

For a long time, scientists have observed that, all other things being equal, riffles tend to be substantially wider than other in-channel landforms,[7] but only recently has there been high enough quality of river maps to confirm that this is true.[8] The physics mechanism that explains why this happens is called flow convergence routing.[9][10] This mechanism may be used in river engineering to design self-sustainable riffles,[11][12] given a suitable sediment supply and flow regime. When an in-channel landform is shallow and narrow, instead of shallow and wide, it is called a nozzle.

Importance to Environment edit

Riffles are very important to the life in a stream, and many aquatic species rely on them in one way or another. Many species of benthic macroinvertebrates rely on the highly oxygenated, fairly unsedimented waters present in a riffle. Many species of fish, including rare and endangered species use riffles to spawn in. Not only do fish spawn in and around riffles, they are also productive feeding grounds for fish, and in turn other predators that feed on fish. Riffles also serve to aerate the water, increasing the amount of dissolved oxygen in the body of water. [13] Water with high and relatively stable levels of dissolved oxygen is typically considered to be a healthy ecosystem because it can generally support greater biodiversity and total biomass.

Macroinvertebrates in riffles edit

Litter patches are a collection of leaves, coarse particulate organic matter, and small woody stems that can be found throughout riffles.[14] In riffles, these patches form at a velocity between 13 and 89 cm/sec, which allows for certain types of litter to be more abundant in riffles because they can stand up to the flow.[14] Leaf litter is most commonly found in riffles, and thus influenced the type of macroinvertebrate functional group is found in riffles, like stoneflies being the dominant shredder species found in riffles.[14] Other macroinvertebrates found in riffles are mayflies (Ephemeroptera). While, in general, the population densities are higher in riffles than pools, some groups like flies Diptera are somewhat less present in riffles, with a low density in riffles compared to pools. [15] Nonbiting midges(Diptera, Chironomidae) and aquatic worms (Class Oligochaeta) are also located in riffles.[16]

 
A raft in a Class II- riffle on the Middle Fork Salmon

Riffles also create a safe habitat for macroinvertebrates because of the varying depth, velocity, and substrate type found in the riffle.[17] Densities of macroinvertebrates vary riffle to riffle because of seasonality or the habitat surrounding the riffle, but macroinvertebrate makeup is fairly consistent.[17] While it can only be assumed that riffles can host a higher level of densities because of higher dissolved oxygen levels, there is a proven positive association between phosphate levels and macroinvertebrates in riffles, indicating that phosphate is an important nutrient for them.[17] Seasonality is important for macroinvertebrate densities, and is characterized by temperature, like summer and winter, or it can be characterized by wetness, like wet and dry seasons. Macroinvertebrates are found in lower abundance during the rainy or wet season due to the high, constant amount of water into the riffle changing the system’s temperature, water velocity, and the aquatic community structure.[16] Also, food, shelter and low flow rates during the dry season make it a more habitable time for higher densities of macroinvertebrates.[16]

Anthropogenic threats edit

Riffles provide important habitat and food production for various aquatic organisms, but humans have altered aquatic ecosystems worldwide through infrastructure and land use changes.[18] Human interference of stream or river flow decreases sediment sizes, resulting in less riffles.[19]

Specifically, weirs and other dams have reduced existing riffles by flattening the channel with smaller substrate, resulting in habitat fragmentation.[19][20] Dam removal has increased in recent times and its effects on riffles vary and are complex, but generally, riffles may redevelop.[18] As these riffles develop, however, they often have a lower biodiversity than the pre-dam ecosystem but benefit aquatic biodiversity in the long term.[18] Following weir removal, riffle fish populations have increased in diversity and density, and these fish have moved upstream to inhabit new riffles that redevelop after dam removal.[18][21] The importance of riffles in supporting diverse assemblages of aquatic biota within streams and rivers may contribute to the increasing trend of dam removal.

Human land use change, specifically development of land, can indirectly affect riffles and riffle quality.[22] Terrestrial vegetation, such as tree branches and leaf litter, contribute to the formation of riffles and stabilization of the ecosystem's channel, and as development reduces this vegetation, riffles may be diminished.[23] Species richness and diversity within riffles are susceptible to anthropogenic land use changes, and management options for restoring these riffles to increase aquatic biodiversity include removing sand and sedimentation and enhancing water flow, to offset impacts from land use change.[20]

Aquaria edit

In the fishkeeping world, a "riffle tank" is one specializing in aquatic life that originates in places with powerful currents like riffles. These are usually emulated with very powerful pumps, shallow 'lowboy' tanks, and larger substrate like cobbles and large gravel. Common inhabitants include North American native fish including Etheostoma, tropical gobies such as Stiphodon, and so called 'hillstream' loaches like Sewellia. Oftentimes, these tanks are lacking in submersed vegetation, instead using botanicals, emersed plants, or no plant material besides aufwuchs on the substrate. [24]

References edit

  1. ^ Leopold, Luna; Wolman, M. Gordon (1957). "River channel patterns: Braided, meandering, and straight". Professional Paper 282-B. United States Geological Survey: 50. {{cite journal}}: Cite journal requires |journal= (help)
  2. ^ "LakeSuperiorStreams - Riffles, runs and pools". www.lakesuperiorstreams.org. Retrieved 2022-02-22.
  3. ^ Wyrick, J. R.; Senter, A. E.; Pasternack, G. B. (2014-04-01). "Revealing the natural complexity of fluvial morphology through 2D hydrodynamic delineation of river landforms". Geomorphology. 210: 14–22. Bibcode:2014Geomo.210...14W. doi:10.1016/j.geomorph.2013.12.013. S2CID 129784282.
  4. ^ Milne, J. A. (1982-04-01). "Bed-material size and the riffle-pool sequence". Sedimentology. 29 (2): 267–278. Bibcode:1982Sedim..29..267M. doi:10.1111/j.1365-3091.1982.tb01723.x. ISSN 1365-3091.
  5. ^ Carling, Paul A.; Orr, Harriet G. (2000-04-01). "Morphology of riffle–pool sequences in the River Severn, England". Earth Surface Processes and Landforms. 25 (4): 369–384. doi:10.1002/(SICI)1096-9837(200004)25:4<353::AID-ESP59>3.0.CO;2-5. ISSN 1096-9837.
  6. ^ Wyrick, J. R.; Pasternack, G. B. (2014-05-15). "Geospatial organization of fluvial landforms in a gravel–cobble river: Beyond the riffle–pool couplet". Geomorphology. 213: 48–65. Bibcode:2014Geomo.213...48W. doi:10.1016/j.geomorph.2013.12.040. S2CID 67792218.
  7. ^ Richards, K. S. (1976-06-01). "Channel width and the riffle-pool sequence". GSA Bulletin. 87 (6): 883–890. Bibcode:1976GSAB...87..883R. doi:10.1130/0016-7606(1976)87<883:CWATRS>2.0.CO;2. ISSN 0016-7606.
  8. ^ Brown, Rocko A.; Pasternack, Gregory B. (2017-01-11). "Bed and width oscillations form coherent patterns in a partially confined, regulated gravel–cobble-bedded river adjusting to anthropogenic disturbances". Earth Surface Dynamics. 5 (1): 1–20. Bibcode:2017ESuD....5....1B. doi:10.5194/esurf-5-1-2017. ISSN 2196-6311.
  9. ^ MacWilliams, Michael L.; Wheaton, Joseph M.; Pasternack, Gregory B.; Street, Robert L.; Kitanidis, Peter K. (2006-10-01). "Flow convergence routing hypothesis for pool-riffle maintenance in alluvial rivers" (PDF). Water Resources Research. 42 (10): W10427. Bibcode:2006WRR....4210427M. doi:10.1029/2005WR004391. ISSN 1944-7973.
  10. ^ Sawyer, April M.; Pasternack, Gregory B.; Moir, Hamish J.; Fulton, Aaron A. (2010-01-15). "Riffle-pool maintenance and flow convergence routing observed on a large gravel-bed river". Geomorphology. 114 (3): 143–160. Bibcode:2010Geomo.114..143S. doi:10.1016/j.geomorph.2009.06.021.
  11. ^ Wheaton, Joseph M.; Brasington, James; Darby, Stephen E.; Merz, Joseph; Pasternack, Gregory B.; Sear, David; Vericat, Damiá (2010-05-01). "Linking geomorphic changes to salmonid habitat at a scale relevant to fish". River Research and Applications. 26 (4): 469–486. doi:10.1002/rra.1305. ISSN 1535-1467. S2CID 130259860.
  12. ^ Brown, Rocko A.; Pasternack, Gregory B.; Lin, Tin (2016-04-01). "The Topographic Design of River Channels for Form-Process Linkages". Environmental Management. 57 (4): 929–942. Bibcode:2016EnMan..57..929B. doi:10.1007/s00267-015-0648-0. ISSN 0364-152X. PMID 26707499. S2CID 206946036.
  13. ^ Gary Chapman (1986). Ambient Aquatic Life Water Quality Criteria for Dissolved Oxygen. U.S. Environmental Protection Agency, Office of Water Regulations and Standards. p. 3.
  14. ^ a b c Kobayashi, S.; Kagaya, T. (2002-04-01). "Differences in litter characteristics and macroinvertebrate assemblages between litter patches in pools and riffles in a headwater stream". Limnology. 3 (1): 37–42. doi:10.1007/s102010200004. ISSN 1439-8621. S2CID 23951148.
  15. ^ Logan, P.; Brooker, M. P. (1983-01-01). "The macroinvertebrate faunas of riffles and pools". Water Research. 17 (3): 263–270. doi:10.1016/0043-1354(83)90179-3. ISSN 0043-1354.
  16. ^ a b c Righi-Cavallaro, Karina Ocampo; Roche, Kennedy Francis; Froehlich, Otávio; Cavallaro, Marcel Rodrigo (September 2010). "Structure of macroinvertebrate communities in riffles of a Neotropical karst stream in the wet and dry seasons". Acta Limnologica Brasiliensia. 22 (3): 306–316. doi:10.4322/actalb.02203007. ISSN 2179-975X.
  17. ^ a b c Cook, Danielle R.; Sullivan, S. Mažeika P. (2018). "Associations between riffle development and aquatic biota following lowhead dam removal". Environmental Monitoring and Assessment. 190 (6): 339. doi:10.1007/s10661-018-6716-1. ISSN 0167-6369. PMC 5945803. PMID 29748723.
  18. ^ a b c d Cook, Danielle R.; Sullivan, S. Mažeika P. (2018). "Associations between riffle development and aquatic biota following lowhead dam removal". Environmental Monitoring and Assessment. 190 (6): 339. doi:10.1007/s10661-018-6716-1. ISSN 0167-6369. PMC 5945803. PMID 29748723.
  19. ^ a b Salant, Nira L.; Schmidt, John C.; Budy, Phaedra; Wilcock, Peter R. (2012). "Unintended consequences of restoration: Loss of riffles and gravel substrates following weir installation". Journal of Environmental Management. 109: 154–163. doi:10.1016/j.jenvman.2012.05.013. ISSN 0301-4797. PMID 22728828.
  20. ^ a b Faulks, Leanne K.; Gilligan, Dean M.; Beheregaray, Luciano B. (2011). "The role of anthropogenic vs. natural in-stream structures in determining connectivity and genetic diversity in an endangered freshwater fish, Macquarie perch (Macquaria australasica): Anthropogenic vs. natural in-stream structures in M. australasica". Evolutionary Applications. 4 (4): 589–601. doi:10.1111/j.1752-4571.2011.00183.x. PMC 3352423. PMID 25568007.
  21. ^ Bushaw-Newton, Karen L.; Hart, David D.; Pizzuto, James E.; Thomson, James R.; Egan, Jennifer; Ashley, Jeffrey T.; Johnson, Thomas E.; Horwitz, Richard J.; Keeley, Melissa; Lawrence, Joy; Charles, Don (2002). "An Integrative Approach Towards Understanding Ecological Responses to Dam Removal: The Manatawny Creek Study". Journal of the American Water Resources Association. 38 (6): 1581–1599. Bibcode:2002JAWRA..38.1581B. doi:10.1111/j.1752-1688.2002.tb04366.x. ISSN 1093-474X. S2CID 129641512.
  22. ^ MALONEY, KELLY O.; WELLER, DONALD E. (2010). "Anthropogenic disturbance and streams: land use and land-use change affect stream ecosystems via multiple pathways". Freshwater Biology. 56 (3): 611–626. doi:10.1111/j.1365-2427.2010.02522.x. ISSN 0046-5070.
  23. ^ Amaral, P. H. M. d.; Silveira, L. S. d.; Rosa, B. F. J. V.; Oliveira, V. C. d.; Alves, R. d. G. (2015). "Influence of Habitat and Land Use on the Assemblages of Ephemeroptera, Plecoptera, and Trichoptera in Neotropical Streams". Journal of Insect Science. 15 (1): 60. doi:10.1093/jisesa/iev042. ISSN 1536-2442. PMC 4535583. PMID 25989807.
  24. ^ Setting up a Riffle Tank, by Cliff Zoller

January 10, 2024
riffle, other, uses, disambiguation, riffle, shallow, landform, flowing, channel, colloquially, shallow, place, river, where, water, flows, quickly, past, rocks, however, geology, riffle, specific, characteristics, onega, river, contents, topographic, sediment. For other uses see Riffle disambiguation A riffle is a shallow landform in a flowing channel 1 Colloquially it is a shallow place in a river where water flows quickly past rocks 2 However in geology a riffle has specific characteristics Riffle on the Onega River Contents 1 Topographic sedimentary and hydraulic indicators 2 Importance to Environment 2 1 Macroinvertebrates in riffles 3 Anthropogenic threats 4 Aquaria 5 ReferencesTopographic sedimentary and hydraulic indicators editRiffles are almost always found to have a very low discharge compared to the flow that fills the channel 3 approximately 10 20 and as a result the water moving over a riffle appears shallow and fast with a wavy disturbed water surface The water s surface over a riffle at low flow also has a much steeper slope than that over other in channel landforms Channel sections with a mean water surface slope of roughly 0 1 to 0 5 exhibit riffles though they can occur in steeper or gentler sloping channels with coarser or finer bed materials respectively Except in the period after a flood when fresh material is deposited on a riffle the sediment on the riverbed in a riffle is usually much coarser than on that in any other in channel landform Terrestrial valleys normally consist of channels geometric depressions in the valley floor carved by flowing water and overbank regions that include floodplains and terraces Some channels have shapes and sizes that hardly change along the river these do not have riffles However many channels exhibit readily apparent changes in width bed elevation and slope In these cases scientists realized that the riverbed often tends to rise and fall with distance downstream relative to an average elevation of the river s slope That led scientists to map the bed elevation down the deepest path in a channel called the thalweg to obtain a longitudinal profile Then the piecewise linear slope of the river is computed and removed to leave just the rise and fall of the elevation about the channel s trendline According to the zero crossing method 4 5 riffles are all the locations along the channel whose residual elevation is greater than zero Because of the prevalence of this method for identifying and mapping riffles riffles are often thought of as part of a paired sequence alternating with pools the lows between the riffles However modern topographic maps of rivers with meter scale resolution reveal that rivers exhibit a diversity of in channel landforms 6 For a long time scientists have observed that all other things being equal riffles tend to be substantially wider than other in channel landforms 7 but only recently has there been high enough quality of river maps to confirm that this is true 8 The physics mechanism that explains why this happens is called flow convergence routing 9 10 This mechanism may be used in river engineering to design self sustainable riffles 11 12 given a suitable sediment supply and flow regime When an in channel landform is shallow and narrow instead of shallow and wide it is called a nozzle Importance to Environment editRiffles are very important to the life in a stream and many aquatic species rely on them in one way or another Many species of benthic macroinvertebrates rely on the highly oxygenated fairly unsedimented waters present in a riffle Many species of fish including rare and endangered species use riffles to spawn in Not only do fish spawn in and around riffles they are also productive feeding grounds for fish and in turn other predators that feed on fish Riffles also serve to aerate the water increasing the amount of dissolved oxygen in the body of water 13 Water with high and relatively stable levels of dissolved oxygen is typically considered to be a healthy ecosystem because it can generally support greater biodiversity and total biomass Macroinvertebrates in riffles edit Litter patches are a collection of leaves coarse particulate organic matter and small woody stems that can be found throughout riffles 14 In riffles these patches form at a velocity between 13 and 89 cm sec which allows for certain types of litter to be more abundant in riffles because they can stand up to the flow 14 Leaf litter is most commonly found in riffles and thus influenced the type of macroinvertebrate functional group is found in riffles like stoneflies being the dominant shredder species found in riffles 14 Other macroinvertebrates found in riffles are mayflies Ephemeroptera While in general the population densities are higher in riffles than pools some groups like flies Diptera are somewhat less present in riffles with a low density in riffles compared to pools 15 Nonbiting midges Diptera Chironomidae and aquatic worms Class Oligochaeta are also located in riffles 16 nbsp A raft in a Class II riffle on the Middle Fork SalmonRiffles also create a safe habitat for macroinvertebrates because of the varying depth velocity and substrate type found in the riffle 17 Densities of macroinvertebrates vary riffle to riffle because of seasonality or the habitat surrounding the riffle but macroinvertebrate makeup is fairly consistent 17 While it can only be assumed that riffles can host a higher level of densities because of higher dissolved oxygen levels there is a proven positive association between phosphate levels and macroinvertebrates in riffles indicating that phosphate is an important nutrient for them 17 Seasonality is important for macroinvertebrate densities and is characterized by temperature like summer and winter or it can be characterized by wetness like wet and dry seasons Macroinvertebrates are found in lower abundance during the rainy or wet season due to the high constant amount of water into the riffle changing the system s temperature water velocity and the aquatic community structure 16 Also food shelter and low flow rates during the dry season make it a more habitable time for higher densities of macroinvertebrates 16 Anthropogenic threats editRiffles provide important habitat and food production for various aquatic organisms but humans have altered aquatic ecosystems worldwide through infrastructure and land use changes 18 Human interference of stream or river flow decreases sediment sizes resulting in less riffles 19 Specifically weirs and other dams have reduced existing riffles by flattening the channel with smaller substrate resulting in habitat fragmentation 19 20 Dam removal has increased in recent times and its effects on riffles vary and are complex but generally riffles may redevelop 18 As these riffles develop however they often have a lower biodiversity than the pre dam ecosystem but benefit aquatic biodiversity in the long term 18 Following weir removal riffle fish populations have increased in diversity and density and these fish have moved upstream to inhabit new riffles that redevelop after dam removal 18 21 The importance of riffles in supporting diverse assemblages of aquatic biota within streams and rivers may contribute to the increasing trend of dam removal Human land use change specifically development of land can indirectly affect riffles and riffle quality 22 Terrestrial vegetation such as tree branches and leaf litter contribute to the formation of riffles and stabilization of the ecosystem s channel and as development reduces this vegetation riffles may be diminished 23 Species richness and diversity within riffles are susceptible to anthropogenic land use changes and management options for restoring these riffles to increase aquatic biodiversity include removing sand and sedimentation and enhancing water flow to offset impacts from land use change 20 Aquaria editIn the fishkeeping world a riffle tank is one specializing in aquatic life that originates in places with powerful currents like riffles These are usually emulated with very powerful pumps shallow lowboy tanks and larger substrate like cobbles and large gravel Common inhabitants include North American native fish including Etheostoma tropical gobies such as Stiphodon and so called hillstream loaches like Sewellia Oftentimes these tanks are lacking in submersed vegetation instead using botanicals emersed plants or no plant material besides aufwuchs on the substrate 24 References edit Leopold Luna Wolman M Gordon 1957 River channel patterns Braided meandering and straight Professional Paper 282 B United States Geological Survey 50 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help LakeSuperiorStreams Riffles runs and pools www lakesuperiorstreams org Retrieved 2022 02 22 Wyrick J R Senter A E Pasternack G B 2014 04 01 Revealing the natural complexity of fluvial morphology through 2D hydrodynamic delineation of river landforms Geomorphology 210 14 22 Bibcode 2014Geomo 210 14W doi 10 1016 j geomorph 2013 12 013 S2CID 129784282 Milne J A 1982 04 01 Bed material size and the riffle pool sequence Sedimentology 29 2 267 278 Bibcode 1982Sedim 29 267M doi 10 1111 j 1365 3091 1982 tb01723 x ISSN 1365 3091 Carling Paul A Orr Harriet G 2000 04 01 Morphology of riffle pool sequences in the River Severn England Earth Surface Processes and Landforms 25 4 369 384 doi 10 1002 SICI 1096 9837 200004 25 4 lt 353 AID ESP59 gt 3 0 CO 2 5 ISSN 1096 9837 Wyrick J R Pasternack G B 2014 05 15 Geospatial organization of fluvial landforms in a gravel cobble river Beyond the riffle pool couplet Geomorphology 213 48 65 Bibcode 2014Geomo 213 48W doi 10 1016 j geomorph 2013 12 040 S2CID 67792218 Richards K S 1976 06 01 Channel width and the riffle pool sequence GSA Bulletin 87 6 883 890 Bibcode 1976GSAB 87 883R doi 10 1130 0016 7606 1976 87 lt 883 CWATRS gt 2 0 CO 2 ISSN 0016 7606 Brown Rocko A Pasternack Gregory B 2017 01 11 Bed and width oscillations form coherent patterns in a partially confined regulated gravel cobble bedded river adjusting to anthropogenic disturbances Earth Surface Dynamics 5 1 1 20 Bibcode 2017ESuD 5 1B doi 10 5194 esurf 5 1 2017 ISSN 2196 6311 MacWilliams Michael L Wheaton Joseph M Pasternack Gregory B Street Robert L Kitanidis Peter K 2006 10 01 Flow convergence routing hypothesis for pool riffle maintenance in alluvial rivers PDF Water Resources Research 42 10 W10427 Bibcode 2006WRR 4210427M doi 10 1029 2005WR004391 ISSN 1944 7973 Sawyer April M Pasternack Gregory B Moir Hamish J Fulton Aaron A 2010 01 15 Riffle pool maintenance and flow convergence routing observed on a large gravel bed river Geomorphology 114 3 143 160 Bibcode 2010Geomo 114 143S doi 10 1016 j geomorph 2009 06 021 Wheaton Joseph M Brasington James Darby Stephen E Merz Joseph Pasternack Gregory B Sear David Vericat Damia 2010 05 01 Linking geomorphic changes to salmonid habitat at a scale relevant to fish River Research and Applications 26 4 469 486 doi 10 1002 rra 1305 ISSN 1535 1467 S2CID 130259860 Brown Rocko A Pasternack Gregory B Lin Tin 2016 04 01 The Topographic Design of River Channels for Form Process Linkages Environmental Management 57 4 929 942 Bibcode 2016EnMan 57 929B doi 10 1007 s00267 015 0648 0 ISSN 0364 152X PMID 26707499 S2CID 206946036 Gary Chapman 1986 Ambient Aquatic Life Water Quality Criteria for Dissolved Oxygen U S Environmental Protection Agency Office of Water Regulations and Standards p 3 a b c Kobayashi S Kagaya T 2002 04 01 Differences in litter characteristics and macroinvertebrate assemblages between litter patches in pools and riffles in a headwater stream Limnology 3 1 37 42 doi 10 1007 s102010200004 ISSN 1439 8621 S2CID 23951148 Logan P Brooker M P 1983 01 01 The macroinvertebrate faunas of riffles and pools Water Research 17 3 263 270 doi 10 1016 0043 1354 83 90179 3 ISSN 0043 1354 a b c Righi Cavallaro Karina Ocampo Roche Kennedy Francis Froehlich Otavio Cavallaro Marcel Rodrigo September 2010 Structure of macroinvertebrate communities in riffles of a Neotropical karst stream in the wet and dry seasons Acta Limnologica Brasiliensia 22 3 306 316 doi 10 4322 actalb 02203007 ISSN 2179 975X a b c Cook Danielle R Sullivan S Mazeika P 2018 Associations between riffle development and aquatic biota following lowhead dam removal Environmental Monitoring and Assessment 190 6 339 doi 10 1007 s10661 018 6716 1 ISSN 0167 6369 PMC 5945803 PMID 29748723 a b c d Cook Danielle R Sullivan S Mazeika P 2018 Associations between riffle development and aquatic biota following lowhead dam removal Environmental Monitoring and Assessment 190 6 339 doi 10 1007 s10661 018 6716 1 ISSN 0167 6369 PMC 5945803 PMID 29748723 a b Salant Nira L Schmidt John C Budy Phaedra Wilcock Peter R 2012 Unintended consequences of restoration Loss of riffles and gravel substrates following weir installation Journal of Environmental Management 109 154 163 doi 10 1016 j jenvman 2012 05 013 ISSN 0301 4797 PMID 22728828 a b Faulks Leanne K Gilligan Dean M Beheregaray Luciano B 2011 The role of anthropogenic vs natural in stream structures in determining connectivity and genetic diversity in an endangered freshwater fish Macquarie perch Macquaria australasica Anthropogenic vs natural in stream structures in M australasica Evolutionary Applications 4 4 589 601 doi 10 1111 j 1752 4571 2011 00183 x PMC 3352423 PMID 25568007 Bushaw Newton Karen L Hart David D Pizzuto James E Thomson James R Egan Jennifer Ashley Jeffrey T Johnson Thomas E Horwitz Richard J Keeley Melissa Lawrence Joy Charles Don 2002 An Integrative Approach Towards Understanding Ecological Responses to Dam Removal The Manatawny Creek Study Journal of the American Water Resources Association 38 6 1581 1599 Bibcode 2002JAWRA 38 1581B doi 10 1111 j 1752 1688 2002 tb04366 x ISSN 1093 474X S2CID 129641512 MALONEY KELLY O WELLER DONALD E 2010 Anthropogenic disturbance and streams land use and land use change affect stream ecosystems via multiple pathways Freshwater Biology 56 3 611 626 doi 10 1111 j 1365 2427 2010 02522 x ISSN 0046 5070 Amaral P H M d Silveira L S d Rosa B F J V Oliveira V C d Alves R d G 2015 Influence of Habitat and Land Use on the Assemblages of Ephemeroptera Plecoptera and Trichoptera in Neotropical Streams Journal of Insect Science 15 1 60 doi 10 1093 jisesa iev042 ISSN 1536 2442 PMC 4535583 PMID 25989807 Setting up a Riffle Tank by Cliff Zoller Retrieved from https en wikipedia org w index php title Riffle amp oldid 1194540603, wikipedia, wiki, book, books, library,

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