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Hyporheic zone

February 15, 2024

The hyporheic zone is the region of sediment and porous space beneath and alongside a stream bed, where there is mixing of shallow groundwater and surface water. The flow dynamics and behavior in this zone (termed hyporheic flow or underflow) is recognized to be important for surface water/groundwater interactions, as well as fish spawning, among other processes.[1] As an innovative urban water management practice, the hyporheic zone can be designed by engineers and actively managed for improvements in both water quality and riparian habitat.[2]

The assemblages of organisms that inhabits this zone are called hyporheos.

The term hyporheic was originally coined by Traian Orghidan[3] in 1959 by combining two Greek words: hypo (below) and rheos (flow).

Hyporheic zone and hydrology edit

 
Hyporheic zone process

The hyporheic zone is the area of rapid exchange, where water is moved into and out of the stream bed and carries dissolved gas and solutes, contaminants, microorganisms and particles with it.[4] Depending on the underlying geology and topography, the hyporheic zone can be only several centimeters deep, or extend up to tens of meters laterally or deep.

The conceptual framework of the hyporheic zone as both a mixing and storage zone are integral to the study of hydrology. The first key concept related to the hyporheic zone is that of residence time; water in the channel moves at a much faster rate compared to the hyporheic zone, so this flow of slower water effectively increases the water residence time within the stream channel. Water residence times influence nutrient and carbon processing rates. Longer residence times promote dissolved solute retention, which can be later released back into the channel, delaying or attenuating the signals produced by the stream channel.[5]

The other key concept is that of hyporheic exchange,[6][7] or the speed at which water enters or leaves the subsurface zone. Stream water enters the hyporheic zone temporarily, but eventually the stream water reenters the surface channel or contributes to groundwater storage. The rate of hyporheic exchange is influenced by streambed structure, with shorter water flow paths created by streambed roughness.[8][9] Longer flowpaths are induced by geomorphic features, such as stream meander patterns, pool-riffle sequences, large woody debris dams, and other features.

The hyporheic zone and its interactions influence the volume of stream water that is moved downstream. Gaining reaches indicate that groundwater is discharged into the stream as water moves downstream, so that the volume of water in the main channel increases from upstream to downstream. Conversely, when surface water infiltrates into the groundwater zone (thereby resulting in a net loss of surface water), then that stream reach is considered to be "losing" water.

The hyporheic zone provides a variety of ecological benefits. Examples include:[10]

  • Habitat and shelter for different species of fish, aquatic plants and interstitial organisms;
  • Reduction of the concentration of pollutants dissolved in the stream water;
  • Control on the water and solute exchange between the main stream and the groundwater;
  • Mitigation of river water temperature.

Studying the hyporheic zone edit

A stream or river ecosystem is more than just the flowing water that can be seen on the surface: rivers are connected to the adjacent riparian areas.[11] Therefore, streams and rivers include the dynamic hyporheic zone that lies below and lateral to the main channel. Because the hyporheic zone lies underneath the surface water, it can be difficult to identify, quantify, and observe. However, the hyporheic zone is a zone of biological and physical activity, and therefore has functional significance for stream and river ecosystems.[12] Researchers use tools such as wells and piezometers, conservative and reactive tracers,[13] and transport models that account for advection and dispersion of water in both the stream channel and the subsurface.[14] These tools can be used independently to study water movement through the hyporheic zone and to the stream channel, but are often complementary for a more accurate picture of water dynamics in the channel as a whole.

Biogeochemical significance edit

The hyporheic zone is an ecotone between the stream and subsurface: it is a dynamic area of mixing between surface water and groundwater at the sediment-water interface. From a biogeochemical perspective, groundwater is often low in dissolved oxygen but carries dissolved nutrients. Conversely, stream water from the main channel contains higher dissolved oxygen and lower nutrients. This creates a biogeochemical gradient, which can exist at varying depths depending on the extent of the hyporheic zone. Often, the hyporheic zone is dominated by heterotrophic microorganisms that process the dissolved nutrients exchanged at this interface.

Hyporheic zone: main characteristics and causes of the hyporheic exchange edit

The main differences between the surface water and groundwater concern the oxygen concentration, the temperature and the pH.[15] As interface region between the main stream and the groundwater the hyporheic zone is subjected to physic-chemical gradients generating biochemical reactions able to regulate the behavior of the chemical compounds and the aquatic organisms within the exchange area.[16] The hyporheic zone provides an important contribution to the attenuation of contaminants dissolved in the channel water[17] and to the cycle of energy, nutrients and organic compounds.[18] Moreover, it exhibits a significant control on the transport of pollutants across the river basin.[19]

The main factors affecting the hyporheic exchange are:[20]

  • Underlying aquifer geometry and hydraulic properties[21][22]
  • Temporal variation in water table height[23]
  • Topographic characteristics and permeability of the streambed[24]
  • Horizontal gradients generated by changes in the stream channel's shape[25]

References edit

  1. ^ Lewandowski, Jörg (2019). "Is the hyporheic zone relevant beyond the scientific community?". Water. 11 (11): 2230. doi:10.3390/w11112230. hdl:20.500.11850/382125.
  2. ^ Lawrence, J.E.; M. Skold; F.A. Hussain; D. Silverman; V.H. Resh; D.L. Sedlak; R.G. Luthy; J.E. McCray (14 August 2013). "Hyporheic Zone in Urban Streams: A Review and Opportunities for Enhancing Water Quality and Improving Aquatic Habitat by Active Management". Environmental Engineering Science. 47 (8): 480–501. doi:10.1089/ees.2012.0235.
  3. ^ Orghidan, T. (1959). "Ein neuer Lebensraum des unterirdischen Wassers: Der hyporheische Biotop". Archiv für Hydrobiologie. 55: 392–414.
  4. ^ Bencala, Kenneth E. (2000). "Hyporheic zone hydrological processes". Hydrological Processes. 14 (15): 2797–2798. Bibcode:2000HyPr...14.2797B. doi:10.1002/1099-1085(20001030)14:15<2797::AID-HYP402>3.0.CO;2-6. ISSN 1099-1085.
  5. ^ Grimm, Nancy B.; Fisher, Stuart G. (1984-04-01). "Exchange between interstitial and surface water: Implications for stream metabolism and nutrient cycling". Hydrobiologia. 111 (3): 219–228. doi:10.1007/BF00007202. ISSN 1573-5117. S2CID 40029109.
  6. ^ Findlay, Stuart (1995). "Importance of surface-subsurface exchange in stream ecosystems: The hyporheic zone". Limnology and Oceanography. 40 (1): 159–164. Bibcode:1995LimOc..40..159F. doi:10.4319/lo.1995.40.1.0159. ISSN 1939-5590.
  7. ^ Bencala, Kenneth E. (2006), "Hyporheic Exchange Flows", Encyclopedia of Hydrological Sciences, American Cancer Society, doi:10.1002/0470848944.hsa126, ISBN 9780470848944
  8. ^ Kasahara, Tamao; Wondzell, Steven M. (2003). "Geomorphic controls on hyporheic exchange flow in mountain streams". Water Resources Research. 39 (1): SBH 3–1–SBH 3-14. Bibcode:2003WRR....39.1005K. doi:10.1029/2002WR001386. ISSN 1944-7973.
  9. ^ Harvey, Judson W.; Bencala, Kenneth E. (1993). "The Effect of streambed topography on surface-subsurface water exchange in mountain catchments". Water Resources Research. 29 (1): 89–98. Bibcode:1993WRR....29...89H. doi:10.1029/92WR01960. ISSN 1944-7973.
  10. ^ The hyporheic handbook: a handbook on the groundwater-surface water interface and hyporheic zone for environment managers. Environment Agency. 2009. ISBN 978-1-84911-131-7.
  11. ^ Stanford, Jack A.; Ward, James V. (March 1993). "An ecosystem perspective of alluvial rivers: connectivity and the hyporheic corridor | Scinapse | Academic search engine for paper". Journal of the North American Benthological Society. 12 (1): 48–60. doi:10.2307/1467685. JSTOR 1467685. S2CID 84122703. Retrieved 2019-03-15.
  12. ^ Boulton, Andrew J.; Findlay, Stuart; Marmonier, Pierre; Stanley, Emily H.; Valett, H. Maurice (1998-11-01). "The functional significance of the hyporheic zone in streams and rivers". Annual Review of Ecology and Systematics. 29 (1): 59–81. doi:10.1146/annurev.ecolsys.29.1.59. ISSN 0066-4162.
  13. ^ Mulholland, Patrick J.; Tank, Jennifer L.; Sanzone, Diane M.; Wollheim, Wilfred M.; Peterson, Bruce J.; Webster, Jackson R.; Meyer, Judy L. (2000). "Nitrogen Cycling in a Forest Stream Determined by a 15n Tracer Addition". Ecological Monographs. 70 (3): 471–493. doi:10.1890/0012-9615(2000)070[0471:NCIAFS]2.0.CO;2. hdl:10919/46856. ISSN 1557-7015.
  14. ^ Bencala, Kenneth E.; Walters, Roy A. (1983). "Simulation of solute transport in a mountain pool-and-riffle stream: A transient storage model". Water Resources Research. 19 (3): 718–724. Bibcode:1983WRR....19..718B. doi:10.1029/WR019i003p00718. hdl:2027/uc1.31210024756569. ISSN 1944-7973.
  15. ^ The hyporheic handbook : a handbook on the groundwater-surface water interface and hyporheic zone for environment managers. Environment Agency. 2009. ISBN 9781849111317.
  16. ^ Brunke, Matthias; Gonser, Tom (1997). "The ecological significance of exchange processes between rivers and groundwater". Freshwater Biology. 37 (1): 1–33. doi:10.1046/j.1365-2427.1997.00143.x. ISSN 1365-2427.
  17. ^ Gandy, C. J.; Smith, J. W. N.; Jarvis, A. P. (15 February 2007). "Attenuation of mining-derived pollutants in the hyporheic zone: A review". Science of the Total Environment. 373 (2): 435–446. Bibcode:2007ScTEn.373..435G. doi:10.1016/j.scitotenv.2006.11.004. ISSN 0048-9697. PMID 17173955.
  18. ^ White, David S. (1 March 1993). "Perspectives on Defining and Delineating Hyporheic Zones". Journal of the North American Benthological Society. 12 (1): 61–69. doi:10.2307/1467686. ISSN 0887-3593. JSTOR 1467686. S2CID 83923428.
  19. ^ Smith, J. W. N.; Surridge, B. W. J.; Haxton, T. H.; Lerner, D. N. (15 May 2009). "Pollutant attenuation at the groundwater–surface water interface: A classification scheme and statistical analysis using national-scale nitrate data". Journal of Hydrology. 369 (3): 392–402. Bibcode:2009JHyd..369..392S. doi:10.1016/j.jhydrol.2009.02.026. ISSN 0022-1694.
  20. ^ Harvey, F. Edwin; Lee, David R.; Rudolph, David L.; Frape, Shaun K. (November 1997). "Locating groundwater discharge in large lakes using bottom sediment electrical conductivity mapping". Water Resources Research. 33 (11): 2609–2615. Bibcode:1997WRR....33.2609H. doi:10.1029/97WR01702. S2CID 131345414.
  21. ^ Freeze, R. Allan; Witherspoon, P. A. (1967). "Theoretical analysis of regional groundwater flow: 2. Effect of water-table configuration and subsurface permeability variation". Water Resources Research. 3 (2): 623–634. Bibcode:1967WRR.....3..623F. doi:10.1029/WR003i002p00623. ISSN 1944-7973.
  22. ^ Winter, Thomas C. (1995). "Recent advances in understanding the interaction of groundwater and surface water". Reviews of Geophysics. 33 (S2): 985–994. Bibcode:1995RvGeo..33S.985W. doi:10.1029/95RG00115. ISSN 1944-9208.
  23. ^ Pinder, George F.; Sauer, Stanley P. (1971). "Numerical Simulation of Flood Wave Modification Due to Bank Storage Effects". Water Resources Research. 7 (1): 63–70. Bibcode:1971WRR.....7...63P. doi:10.1029/WR007i001p00063. ISSN 1944-7973.
  24. ^ Harvey, Judson W.; Bencala, Kenneth E. (1993). "The Effect of streambed topography on surface-subsurface water exchange in mountain catchments". Water Resources Research. 29 (1): 89–98. Bibcode:1993WRR....29...89H. doi:10.1029/92WR01960. ISSN 1944-7973.
  25. ^ Cardenas, M. Bayani (2009). "A model for lateral hyporheic flow based on valley slope and channel sinuosity". Water Resources Research. 45 (1): W01501. Bibcode:2009WRR....45.1501C. doi:10.1029/2008WR007442. ISSN 1944-7973.

External links edit

 
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February 15, 2024
hyporheic, zone, hyporheic, zone, region, sediment, porous, space, beneath, alongside, stream, where, there, mixing, shallow, groundwater, surface, water, flow, dynamics, behavior, this, zone, termed, hyporheic, flow, underflow, recognized, important, surface,. The hyporheic zone is the region of sediment and porous space beneath and alongside a stream bed where there is mixing of shallow groundwater and surface water The flow dynamics and behavior in this zone termed hyporheic flow or underflow is recognized to be important for surface water groundwater interactions as well as fish spawning among other processes 1 As an innovative urban water management practice the hyporheic zone can be designed by engineers and actively managed for improvements in both water quality and riparian habitat 2 The assemblages of organisms that inhabits this zone are called hyporheos The term hyporheic was originally coined by Traian Orghidan 3 in 1959 by combining two Greek words hypo below and rheos flow Contents 1 Hyporheic zone and hydrology 2 Studying the hyporheic zone 3 Biogeochemical significance 4 Hyporheic zone main characteristics and causes of the hyporheic exchange 5 References 6 External linksHyporheic zone and hydrology edit nbsp Hyporheic zone processThe hyporheic zone is the area of rapid exchange where water is moved into and out of the stream bed and carries dissolved gas and solutes contaminants microorganisms and particles with it 4 Depending on the underlying geology and topography the hyporheic zone can be only several centimeters deep or extend up to tens of meters laterally or deep The conceptual framework of the hyporheic zone as both a mixing and storage zone are integral to the study of hydrology The first key concept related to the hyporheic zone is that of residence time water in the channel moves at a much faster rate compared to the hyporheic zone so this flow of slower water effectively increases the water residence time within the stream channel Water residence times influence nutrient and carbon processing rates Longer residence times promote dissolved solute retention which can be later released back into the channel delaying or attenuating the signals produced by the stream channel 5 The other key concept is that of hyporheic exchange 6 7 or the speed at which water enters or leaves the subsurface zone Stream water enters the hyporheic zone temporarily but eventually the stream water reenters the surface channel or contributes to groundwater storage The rate of hyporheic exchange is influenced by streambed structure with shorter water flow paths created by streambed roughness 8 9 Longer flowpaths are induced by geomorphic features such as stream meander patterns pool riffle sequences large woody debris dams and other features The hyporheic zone and its interactions influence the volume of stream water that is moved downstream Gaining reaches indicate that groundwater is discharged into the stream as water moves downstream so that the volume of water in the main channel increases from upstream to downstream Conversely when surface water infiltrates into the groundwater zone thereby resulting in a net loss of surface water then that stream reach is considered to be losing water The hyporheic zone provides a variety of ecological benefits Examples include 10 Habitat and shelter for different species of fish aquatic plants and interstitial organisms Reduction of the concentration of pollutants dissolved in the stream water Control on the water and solute exchange between the main stream and the groundwater Mitigation of river water temperature Studying the hyporheic zone editA stream or river ecosystem is more than just the flowing water that can be seen on the surface rivers are connected to the adjacent riparian areas 11 Therefore streams and rivers include the dynamic hyporheic zone that lies below and lateral to the main channel Because the hyporheic zone lies underneath the surface water it can be difficult to identify quantify and observe However the hyporheic zone is a zone of biological and physical activity and therefore has functional significance for stream and river ecosystems 12 Researchers use tools such as wells and piezometers conservative and reactive tracers 13 and transport models that account for advection and dispersion of water in both the stream channel and the subsurface 14 These tools can be used independently to study water movement through the hyporheic zone and to the stream channel but are often complementary for a more accurate picture of water dynamics in the channel as a whole Biogeochemical significance editThe hyporheic zone is an ecotone between the stream and subsurface it is a dynamic area of mixing between surface water and groundwater at the sediment water interface From a biogeochemical perspective groundwater is often low in dissolved oxygen but carries dissolved nutrients Conversely stream water from the main channel contains higher dissolved oxygen and lower nutrients This creates a biogeochemical gradient which can exist at varying depths depending on the extent of the hyporheic zone Often the hyporheic zone is dominated by heterotrophic microorganisms that process the dissolved nutrients exchanged at this interface Hyporheic zone main characteristics and causes of the hyporheic exchange editThe main differences between the surface water and groundwater concern the oxygen concentration the temperature and the pH 15 As interface region between the main stream and the groundwater the hyporheic zone is subjected to physic chemical gradients generating biochemical reactions able to regulate the behavior of the chemical compounds and the aquatic organisms within the exchange area 16 The hyporheic zone provides an important contribution to the attenuation of contaminants dissolved in the channel water 17 and to the cycle of energy nutrients and organic compounds 18 Moreover it exhibits a significant control on the transport of pollutants across the river basin 19 The main factors affecting the hyporheic exchange are 20 Underlying aquifer geometry and hydraulic properties 21 22 Temporal variation in water table height 23 Topographic characteristics and permeability of the streambed 24 Horizontal gradients generated by changes in the stream channel s shape 25 References edit Lewandowski Jorg 2019 Is the hyporheic zone relevant beyond the scientific community Water 11 11 2230 doi 10 3390 w11112230 hdl 20 500 11850 382125 Lawrence J E M Skold F A Hussain D Silverman V H Resh D L Sedlak R G Luthy J E McCray 14 August 2013 Hyporheic Zone in Urban Streams A Review and Opportunities for Enhancing Water Quality and Improving Aquatic Habitat by Active Management Environmental Engineering Science 47 8 480 501 doi 10 1089 ees 2012 0235 Orghidan T 1959 Ein neuer Lebensraum des unterirdischen Wassers Der hyporheische Biotop Archiv fur Hydrobiologie 55 392 414 Bencala Kenneth E 2000 Hyporheic zone hydrological processes Hydrological Processes 14 15 2797 2798 Bibcode 2000HyPr 14 2797B doi 10 1002 1099 1085 20001030 14 15 lt 2797 AID HYP402 gt 3 0 CO 2 6 ISSN 1099 1085 Grimm Nancy B Fisher Stuart G 1984 04 01 Exchange between interstitial and surface water Implications for stream metabolism and nutrient cycling Hydrobiologia 111 3 219 228 doi 10 1007 BF00007202 ISSN 1573 5117 S2CID 40029109 Findlay Stuart 1995 Importance of surface subsurface exchange in stream ecosystems The hyporheic zone Limnology and Oceanography 40 1 159 164 Bibcode 1995LimOc 40 159F doi 10 4319 lo 1995 40 1 0159 ISSN 1939 5590 Bencala Kenneth E 2006 Hyporheic Exchange Flows Encyclopedia of Hydrological Sciences American Cancer Society doi 10 1002 0470848944 hsa126 ISBN 9780470848944 Kasahara Tamao Wondzell Steven M 2003 Geomorphic controls on hyporheic exchange flow in mountain streams Water Resources Research 39 1 SBH 3 1 SBH 3 14 Bibcode 2003WRR 39 1005K doi 10 1029 2002WR001386 ISSN 1944 7973 Harvey Judson W Bencala Kenneth E 1993 The Effect of streambed topography on surface subsurface water exchange in mountain catchments Water Resources Research 29 1 89 98 Bibcode 1993WRR 29 89H doi 10 1029 92WR01960 ISSN 1944 7973 The hyporheic handbook a handbook on the groundwater surface water interface and hyporheic zone for environment managers Environment Agency 2009 ISBN 978 1 84911 131 7 Stanford Jack A Ward James V March 1993 An ecosystem perspective of alluvial rivers connectivity and the hyporheic corridor Scinapse Academic search engine for paper Journal of the North American Benthological Society 12 1 48 60 doi 10 2307 1467685 JSTOR 1467685 S2CID 84122703 Retrieved 2019 03 15 Boulton Andrew J Findlay Stuart Marmonier Pierre Stanley Emily H Valett H Maurice 1998 11 01 The functional significance of the hyporheic zone in streams and rivers Annual Review of Ecology and Systematics 29 1 59 81 doi 10 1146 annurev ecolsys 29 1 59 ISSN 0066 4162 Mulholland Patrick J Tank Jennifer L Sanzone Diane M Wollheim Wilfred M Peterson Bruce J Webster Jackson R Meyer Judy L 2000 Nitrogen Cycling in a Forest Stream Determined by a 15n Tracer Addition Ecological Monographs 70 3 471 493 doi 10 1890 0012 9615 2000 070 0471 NCIAFS 2 0 CO 2 hdl 10919 46856 ISSN 1557 7015 Bencala Kenneth E Walters Roy A 1983 Simulation of solute transport in a mountain pool and riffle stream A transient storage model Water Resources Research 19 3 718 724 Bibcode 1983WRR 19 718B doi 10 1029 WR019i003p00718 hdl 2027 uc1 31210024756569 ISSN 1944 7973 The hyporheic handbook a handbook on the groundwater surface water interface and hyporheic zone for environment managers Environment Agency 2009 ISBN 9781849111317 Brunke Matthias Gonser Tom 1997 The ecological significance of exchange processes between rivers and groundwater Freshwater Biology 37 1 1 33 doi 10 1046 j 1365 2427 1997 00143 x ISSN 1365 2427 Gandy C J Smith J W N Jarvis A P 15 February 2007 Attenuation of mining derived pollutants in the hyporheic zone A review Science of the Total Environment 373 2 435 446 Bibcode 2007ScTEn 373 435G doi 10 1016 j scitotenv 2006 11 004 ISSN 0048 9697 PMID 17173955 White David S 1 March 1993 Perspectives on Defining and Delineating Hyporheic Zones Journal of the North American Benthological Society 12 1 61 69 doi 10 2307 1467686 ISSN 0887 3593 JSTOR 1467686 S2CID 83923428 Smith J W N Surridge B W J Haxton T H Lerner D N 15 May 2009 Pollutant attenuation at the groundwater surface water interface A classification scheme and statistical analysis using national scale nitrate data Journal of Hydrology 369 3 392 402 Bibcode 2009JHyd 369 392S doi 10 1016 j jhydrol 2009 02 026 ISSN 0022 1694 Harvey F Edwin Lee David R Rudolph David L Frape Shaun K November 1997 Locating groundwater discharge in large lakes using bottom sediment electrical conductivity mapping Water Resources Research 33 11 2609 2615 Bibcode 1997WRR 33 2609H doi 10 1029 97WR01702 S2CID 131345414 Freeze R Allan Witherspoon P A 1967 Theoretical analysis of regional groundwater flow 2 Effect of water table configuration and subsurface permeability variation Water Resources Research 3 2 623 634 Bibcode 1967WRR 3 623F doi 10 1029 WR003i002p00623 ISSN 1944 7973 Winter Thomas C 1995 Recent advances in understanding the interaction of groundwater and surface water Reviews of Geophysics 33 S2 985 994 Bibcode 1995RvGeo 33S 985W doi 10 1029 95RG00115 ISSN 1944 9208 Pinder George F Sauer Stanley P 1971 Numerical Simulation of Flood Wave Modification Due to Bank Storage Effects Water Resources Research 7 1 63 70 Bibcode 1971WRR 7 63P doi 10 1029 WR007i001p00063 ISSN 1944 7973 Harvey Judson W Bencala Kenneth E 1993 The Effect of streambed topography on surface subsurface water exchange in mountain catchments Water Resources Research 29 1 89 98 Bibcode 1993WRR 29 89H doi 10 1029 92WR01960 ISSN 1944 7973 Cardenas M Bayani 2009 A model for lateral hyporheic flow based on valley slope and channel sinuosity Water Resources Research 45 1 W01501 Bibcode 2009WRR 45 1501C doi 10 1029 2008WR007442 ISSN 1944 7973 External links edit nbsp Look up hyporheic in Wiktionary the free dictionary An article on the hyporheic zone of streams and water purification Includes a diagram nbsp This fluid dynamics related article is a stub You can help Wikipedia by expanding it vte Retrieved from https en wikipedia org w index php title Hyporheic zone amp oldid 1193505326, wikipedia, wiki, book, books, library,

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