Transport of nonsorbing solutes in a streambed with periodic bedforms

Jin, Guangqiu; Tang, Hongwu; Gibbes, Badin; Li, Ling; Barry, David Andrew

doi:10.1016/j.advwatres.2010.09.003

Cited by 78 publications

(105 citation statements)

References 61 publications

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“…Similar simulations could be conducted for streambed ripples. Jin et al (2010) investigated advective-dispersive transport in hyporheic flow caused by bedforms. They found that neglecting dispersion in advection based pumping exchange models can lead to an underestimation of long-term exchange rates and volumes.…”

Section: Heat Exchange and Temperaturementioning

confidence: 99%

Inter‐disciplinary perspectives on processes in the hyporheic zone

et al. 2010

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International audienceThe interface between groundwater and surface water within riverine/riparian ecosystems--the hyporheic zone (HZ)--is experiencing a rapid growth of research interest from a range of scientific disciplines, often with different perspectives. The majority of the multi-disciplinary research aims to elucidate HZ process dynamics and their importance for surface water and groundwater ecohydrology and biogeochemical cycling. This paper presents a critical inter-disciplinary review of recent advances of research centred on the HZ and highlights the current state of knowledge regarding hydrological, biogeochemical and ecohydrological process understanding. The spatial and temporal variability of surface water and groundwater exchange (hyporheic exchange flows), biogeochemical cycling and heat exchange (thermal regime) are considered in relation to both experimental measurements and modelling of these phenomena. We explore how this knowledge has helped to increase our understanding of HZ ecohydrology, and particularly its invertebrate community, the processing of organic matter, trophic cascading and ecosystem engineering by macrophytes and other organisms across a range of spatial and temporal scales. In addition to providing a detailed review of HZ functions, we present an inter-disciplinary perspective on how to advance and integrate HZ process understanding across traditional discipline boundaries. We therefore attempt to highlight knowledge gaps and research needs within the individual disciplines and demonstrate how innovations and advances in research, made within traditional subject-specific boundaries (e.g. hydrology, biochemistry and ecology), can be used to enhance inter-disciplinary scientific progress by cross-system comparisons and fostering of greater dialogue between scientific disciplines

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Section: Heat Exchange and Temperaturementioning

confidence: 99%

Inter‐disciplinary perspectives on processes in the hyporheic zone

et al. 2010

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“…Prior to each experiment, the sand was first thoroughly rinsed with deionized water (four times and 1 h each time) following the method of Jin et al [2010] to remove impurities. It was then washed with salt water of 15 ppt salinity for a sufficiently long time (four times and 1.5 h each time) to ensure that the pore water in the sand had the initial salinity of 15 ppt.…”

Section: Laboratory Experimentsmentioning

confidence: 99%

Effects of salinity variations on pore water flow in salt marshes

Shen

Jin

Xin

et al. 2015

Water Resources Research

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Spatial and temporal salinity variations in surface water and pore water commonly exist in salt marshes under the combined influence of tidal inundation, precipitation, evapotranspiration, and inland freshwater input. Laboratory experiments and numerical simulations were conducted to investigate how density gradients associated with salinity variations affect pore water flow in the salt marsh system. The results showed that upward salinity (density) gradients could lead to flow instability and the formation of salt fingers. These fingers, varying in size with the distance from the creek, modified significantly the pore water flow field, especially in the marsh interior. While the flow instability enhanced local salt transport and mixing considerably, the net effect was small, causing only a slight increase in the overall mass exchange across the marsh surface. In contrast, downward salinity gradients exerted less influence on the pore water flow in the marsh soil and slightly weakened the surface water and groundwater exchange across the marsh surface. Numerical simulations revealed similar density effects on pore water flow at the field scale under realistic conditions. These findings have important implications for studies of marsh soil conditions concerning plant growth as well as nutrient exchange between the marsh and coastal marine system.

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“…Additionally, the wall‐normal Reynolds stresses (Figure d) associated with the shear layer are lessened for the dune on a permeable bed (Figure d), and the zone of high Reynolds stress does not impinge on the bed as in the cases for the impermeable bed dunes. Upwelling flow in the leeside can be seen to be supplied by a positive vertical flow within the underlying pores in this region (Figures d, d, and d (bottom)), with subsurface flow downwelling on the stoss side and upwelling in the leeside (Figure d), as has been documented in previous studies of hyporheic flow and bed forms [ Cardenas and Wilson , ; Janssen et al ., ; Hester et al ., ; Thibodeaux and Boyle , ; Jin et al ., ; Harrison and Clayton , ].…”

Section: Resultsmentioning

confidence: 99%

“…However, while progress has been made into refining the original advective pumping model and extending it to more complex geometrical configurations [ Bardini et al ., ; Stonedahl et al ., ], past research has largely neglected the nonlinearity of the turbulent flow above the bed. Recent numerical models typically treat the surface and subsurface flows as separate, assuming turbulent flows above the bed and Darcian flows beneath [ Cardenas and Wilson , , ; Cardenas et al ., ; Jin et al ., ; Janssen et al ., ]. The coupling is obtained through continuity on mean pressure terms, neglecting the existence of a transition region between the two regions, where unsteady and nonlinear interactions are reasonably expected.…”

Section: Introductionmentioning

confidence: 99%

Effect of bed permeability and hyporheic flow on turbulent flow over bed forms

Blois

Best

Smith

et al. 2014

Geophys. Res. Lett.

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This paper uses particle imaging velocimetry to provide the first measurements detailing the flow field over a porous bed in the presence of bed forms. The results demonstrate that flow downstream of coarse-grained bed forms on permeable beds is fundamentally different to that over impermeable beds. Most significantly, the leeside flow separation cell is greatly modified by jets of fluid emerging from the subsurface, such that reattachment of the separated flow does not occur and the Reynolds stresses bounding the separation zone are substantially lessened. These results shed new light on the underlying flow physics and advance our understanding of both ecological and geomorphological processes associated with permeable bed forms. Water fluxes at the bed interface are critically important for biogeochemical cycling in all rivers, yet mass and momentum exchanges across the bed interface are not routinely incorporated into flow models. Our observations suggest that ignoring such exchange processes in coarse-grained rivers may overlook important implications. These new results also provide insight to explain the distinctive morphology of coarse-grained bed forms, the production of openwork textures in gravels, and the absence of ripples in coarse sands, all of which have implications for modeling and prediction of sediment entrainment and flow resistance.

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Transport of nonsorbing solutes in a streambed with periodic bedforms

Cited by 78 publications

References 61 publications

Inter‐disciplinary perspectives on processes in the hyporheic zone

Inter‐disciplinary perspectives on processes in the hyporheic zone

Effects of salinity variations on pore water flow in salt marshes

Effect of bed permeability and hyporheic flow on turbulent flow over bed forms

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