Advanced search
Publication Cover
Journal of Freshwater Ecology Volume 37, 2022 - Issue 1
Submit an article Journal homepage
1,677
Views
12
CrossRef citations to date
0
Altmetric
Articles

Hyporheic exchange due to in-stream geomorphic structures

Jinghong Fenga College of Hydraulic and Environmental Engineering, China Three Gorges University, Yichang, Hubei, China;b Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaORCID Iconhttps://orcid.org/0000-0002-8517-8304View further author information
ORCID Icon,
Defu Liub Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaCorrespondence[email protected] [email protected]
View further author information
,
Ying Liub Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaCorrespondence[email protected] [email protected]
View further author information
,
Yi Lib Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaView further author information
,
Han Lib Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaView further author information
,
Lihui Chenb Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaView further author information
,
Jingwen Xiaob Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaView further author information
,
Jixin Liub Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaView further author information
&
Jiawei Dongb Hubei Key Laboratory of Ecological Restoration of River-lakes and Algal Utilization, Hubei University of Technology, Wuhan, ChinaView further author information
 show all
Pages 221-241 | Received 19 Jul 2021, Accepted 22 Jan 2022, Published online: 07 Mar 2022

References

  • Azinheira DL, Scott DT, Hession W, Hester ET. 2014. Comparison of effects of inset floodplains and hyporheic exchange induced by in-stream structures on solute retention. Water Resour Res. 50(7):6168–6190.
  • Boulton AJ. 2007. Hyporheic rehabilitation in rivers: restoring vertical connectivity. Freshwater Biol. 52(4):632–650.
  • Boulton AJ, Datry T, Kasahara T, Mutz M, Stanford JA. 2010. Ecology and management of the hyporheic zone: stream-groundwater interactions of running waters and their floodplains. J North Am Benthol Soc. 29(1):26–40.
  • Boulton AJ, Findlay S, Marmonier P, Stanley EH, Valett HM. 1998. The functional significance of the hyporheic zone in streams and rivers. Annu Rev Ecol Syst. 29(1):59–81.
  • Buchanan B, Walter M, Nagle G, Schneider R. 2012. Monitoring and assessment of a river restoration project in central New York. River Res Appl. 28(2):216–233.
  • Cardenas MB. 2006. Dynamics of fluids, heat and solutes along sediment–water interfaces: a multiphysics modeling study [Ph.D. thesis]. The New Mexico Institute of Mining and Technology.
  • Cardenas MB, Wilson JL. 2007. Dunes, turbulent eddies, and interfacial exchange with permeable sediments. Water Resour Res. 43(8):199–212.
  • Cardenas MB, Wilson JL, Haggerty R. 2008. Residence time of bedform-driven hyporheic exchange. Adv Water Resour. 31(10):1382–1386.
  • Chin A, Anderson S, Collison A, Ellis-Sugai BJ, Haltiner JP, Hogervorst JB, Kondolf GM, O’Hirok LS, Purcell AH, Riley AL. 2009. Linking theory and practice for restoration of step-pool streams. Environ Manage. 43(4):645–661.
  • Daniluk TL, Lautz LK, Gordon RP, Endreny TA. 2013. Surface water-groundwater interaction at restored streams and associated reference reaches. Hydrol Process. 27(25):3730–3746.
  • Elliott AH. 1990. Transfer of solutes into and out of streambeds. Rep KH-R-52, WM Keck Lab Hydraul Water Resour, Calif Inst Technol, Pasadena, USA.
  • Endreny T, Lautz L, Siegel D. 2011a. Hyporheic flow path response to hydraulic jumps at river steps: flume and hydrodynamic models. Water Resour Res. 47:W02517.
  • Findlay S. 1995. Importance of surface-subsurface exchange in stream ecosystems: the hyporheic zone. Limnol Oceanogr. 40(1):159–164.
  • Gordon RP, Lautz LK, Daniluk TL. 2013. Spatial patterns of hyporheic exchange and biogeochemical cycling around cross-vane restoration structures: implications for stream restoration design. Water Resour Res. 49(4):2040–2055.
  • Hancock PJ. 2002. Human impacts on the stream-groundwater exchange zone. Environ Manage - New York. 29(6):763–781.
  • Hancock PJ, Boulton AJ, Humphreys WF. 2005. Aquifers and hyporheic zones: towards an ecological understanding of groundwater. Hydrogeol J. 13(1):98–111.
  • Harvey JW, Gooseff M. 2015. River corridor science: hydrologic exchange and ecological consequences from bedforms to basins. Water Resour Res. 51(9):6893–6922.
  • Harvey JW, Wagner BJ. 2000. Quantifying hydrologic interactions between streams and their subsurface hyporheic zones. Streams and Ground Waters: Academic Press, USA. p. 3–44.
  • Herzog SP, Higgins CP, Mccray JE. 2016. Engineered streambeds for induced hyporheic flow: enhanced removal of nutrients, pathogens, and metals from urban streams. J Environ Eng. 142(1):04015053.
  • Hester ET, Doyle MW. 2008. In-stream geomorphic structures as drivers of hyporheic exchange. Water Resour Res. 44(3):893–897.
  • Hester ET, Doyle MW, Poole GC. 2009. The influence of in-stream structures on summer water temperatures via induced hyporheic exchange. Limnol Oceanogr. 54(1):355–367.
  • Hester ET, Gooseff MN. 2010. Moving beyond the banks: hyporheic restoration is fundamental to restoring ecological services and functions of streams. Environ Sci Technol. 44(5):1521–1525.
  • Hester ET, Gooseff MN. 2013. Hyporheic restoration in streams and rivers, in stream restoration in dynamic fluvial systems. Washington, DC: American Geophysical Union.
  • Jiang QH, Jin GQ, Tang HW, Shen CJ, Cheraghi M, Xu JZ, Li L, Barry DA. 2020. Density-dependent solute transport in a layered hyporheic zone. Adv Water Resour. 142:103645.
  • Jin GQ, Tang HW, Gibbes B, Li L, Barry DA. 2010. Transport of nonsorbing solutes in a streambed with periodic bedform. Adv Water Resour. 33(11):1402–1416.
  • Krause S, Hannah DM, Fleckenstein JH. 2009. Hyporheic hydrology: interactions at the groundwater-surface water interface preface. Hydrol Process. 23(15):2103–2107.
  • Lautz LK, Fanelli RM. 2008. Seasonal biogeochemical hotspots in the streambed around restoration structures. Biogeochemistry. 91(1):85–104.
  • Lautz LK, Siegel DI, Bauer RL. 2006. Impact of debris dams on hyporheic interaction along a semi-arid stream. Hydrol Process. 20(1):183–196.
  • Lewandowski J, Arnon S, Banks E, Batelaan O, Betterle A, Broecker T, Coll C, Drummond JD, Garcia JG, Galloway J, et al. 2019. Is the hyporheic zone relevant beyond the scientific community? Water. 11(11):2230.
  • Liu S, Chui T. 2020. Optimal in-stream structure design through considering nitrogen removal in hyporheic zone. Water. 12(5):1399.
  • Menichino GT, Hester ET. 2014. Hydraulic and thermal effects of in-stream structure-induced hyporheic exchange across a range of hydraulic conductivities. Water Resour Res. 50(6):4643–4661.
  • Newbold JD, O’Neill RV, Elwood JW, Van Winkle W. 1982. Nutrient spiraling in streams: implications for nutrient limitation and invertebrate activity. Am Nat. 120(5):628–652.
  • Norman FA, Cardenas MB. 2014. Heat transport in hyporheic zones due to bedforms: an experimental study. Water Resour Res. 10(1):29–38.
  • Packman AI, Bencala KE. 2000. Modeling methods in the study of surface-subsurface hydrologic interactions. Streams and Ground Waters: Academic Press, USA. p. 45–80.
  • Packman AI, Brooks NH, Morgan JJ. 2000. A physicochemical model for colloid exchange between a stream and a sand streambed with bed forms. Water Resour Res. 36(8):2351–2362.
  • Quinino RC, Reis EA, Bessegato LF. 2013. Using the coefficient of determination R2 to test the significance of multiple linear regression. Teach Stat. 35(2):84–88.
  • Ren J, Packman AI. 2004. Stream-subsurface exchange of zinc in the presence of silica and kaolinite colloids. Environ Sci Technol. 38(24):6571–6581.
  • Ren J, Wang X, Zhou Y, Chen B, Men L. 2019. An analysis of the factors affecting hyporheic exchange based on numerical modeling. Water. 11(4):665.
  • Rosgen DL. 2001. The cross-vane, W-Weir and J-Hook vane structures… Their description, design and application for stream stabilization and river restoration. Wetlands Engineering & River Restoration. p. 1–22.
  • Sawyer AH, Cardenas MB. 2009. Hyporheic flow and residence time distributions in heterogeneous cross-bedded sediment. Water Resour Res. 45(8):W08406.
  • Sawyer AH, Cardenas MB. 2012. Effect of experimental wood addition on hyporheic exchange and thermal dynamics in a losing meadow stream. Water Resour Res. 48(10):10537.
  • Sawyer AH, Cardenas MB, Buttles J. 2011. Hyporheic exchange due to channel-spanning logs. Water Resour Res. 47(8):427–438.
  • Smidt SJ, Cullin JA, Ward AS, Robinson J, Zimmer MA, Lautz L, Endreny TA. 2015. A comparison of hyporheic transport at a cross-vane structure and natural riffle. Groundwater. 53(6):859–871.
  • Storey RG, Howard K, Williams DD. 2003. Factors controlling riffle-scale hyporheic exchange flows and their seasonal changes in a gaining stream: a three-dimensional groundwater flow model. Water Resour Res. 39(2):180–189.
  • Suñé V, Carrasco JA. 2005. Efficient implementations of the randomization method with control of the relative error. Comput Oper Res. 32(5):1089–1114.
  • Swanson TE, Cardenas MB. 2010. Diel heat transport within the hyporheic zone of a pool-riffle-pool sequence of a losing stream and evaluation of models for fluid flux estimation using heat. Limnol Oceanogr. 55(4):1741–1754.
  • Tockner K, Pennetzdorfer D, Reiner N, Schiemer F, Ward J. 1999. Hydrological connectivity, and the exchange of organic matter and nutrients in a dynamic river-floodplain system (Danube, Austria). Freshwater Biol. 41(3):521–535.
  • Triska FJ, Kennedy VC, Avanzino RJ, Zellweger GW, Bencala KE. 1989. Retention and transport of nutrients in a third-order stream: channel processes. Ecology. 70(6):1877–1892.
  • Ward AS, Gooseff MN, Johnson PA. 2011. How can subsurface modifications to hydraulic conductivity be designed as stream restoration structures? Analysis of Vaux’s conceptual models to enhance hyporheic exchange. Water Resour Res. 47(8):W08512.
  • Wilcox DC. 2006. Turbulence modeling for CFD (Third Edition). DCW Industries, Incorporated, USA.
  • Winter TC, Harvey JW, Franke OL, Alley WM. 1998. Ground water and surface water: a single resource. U.S. Geological Survey Publications. p. 79.
  • Zhou T, Endreny TA. 2013. Reshaping of the hyporheic zone beneath river restoration structures: flume and hydrodynamic experiments. Water Resour Res. 49(8):5009–5020.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.