Making water flow: a comparison of the hydrodynamic characteristics of 12 different benthic biological flumes

Jonsson, Per R.; Duren, Luca A. van; Amielh, Muriel; Asmus, Ragnhild; Aspden, Rebecca J.; Daunys, Darius; Friedrichs, Michael; Friend, Patrick L.; Olivier, Frédéric; Pope, Nick; Precht, Elimar; Sauriau, Pierre-Guy; Schaaff, Estelle

doi:10.1007/s10452-006-9049-z

Cited by 41 publications

(34 citation statements)

References 50 publications

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“…It is a straight recirculating facility, which was designed and built [Dumas, 2004] to study the erosion of sediments and provide a wider bed shear stress range than in the flume already used at the Centre d'Océanologie de Marseille (see for details Jonsson et al [2006]). The overall length of the channel is 13.5 m. Its test section is 8 m long, with a rectangular cross section of 0.6 m width.…”

Section: Methodsmentioning

confidence: 99%

Erosion threshold of saturated natural cohesive sediments: Modeling and experiments

Ternat

Boyer

Anselmet

et al. 2008

Water Resources Research

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[1] Predicting the erosion resistance of saturated natural sediments requires taking into account cohesion, which results from interactions between clay particles. The current paper describes a combined experimental and theoretical examination of the threshold conditions for a mixture of clays and sands. Erosion threshold measured values are larger than those predicted from noncohesive models. Beyond the usual dependence on grain size, a significant correlation between erosion threshold and porosity measurements is confirmed for heterogenous mixtures of grains with particle Reynolds number lower than 5, for pH values in the range of 6-8, and under freshwater conditions. A model of the erosion criterion is proposed. First, a cohesion force between two spherical particles is introduced into the usual erosion criterion. This reveals a specific function of the cohesion force, called cohesion function. The force we consider is the long-range van der Waals interaction. Then, multiple interactions between one particle and those surrounding it are counted and modeled on the basis of both the coordination number and the porosity. Finally, the overall erosion threshold for the sediment bed is inferred from the average of the multiple interactions over the grain size distribution. The model highlights that cohesion comes from clay particles (about 2 10 À6 m) and can affect the entire grain size range (from clays to sands) by means of coordination. The model relevance is assessed by comparison with experimental thresholds obtained from resuspension campaigns. The results show that the proposed cohesion model offers good agreement with experimental data.

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Section: Methodsmentioning

confidence: 99%

Erosion threshold of saturated natural cohesive sediments: Modeling and experiments

Ternat

Boyer

Anselmet

et al. 2008

Water Resources Research

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“…One is the particle entrainment simulator (PES) designed by Tsai and Lick [4]; the other is flume tank [5]. Among flume tanks, annular flume has been extensively used to investigate various physical, chemical and biological factors which may influence the stability and erodibility of natural cohesive sediments [6][7][8][9][10].…”

mentioning

confidence: 99%

Remobilization of heavy metals during the resuspension of Liangshui River sediments using an annular flume

Huang

Yang

et al. 2012

Chin. Sci. Bull.

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The release and transport of heavy metals (Ni, Cr, Cu and Pb) from Liangshui River sediments into the overlying water column during the resuspension event were determined using an annular flume with a velocity ranging from 0.15 to 0.35 m/s. It is shown that the suspended particulate matters (SPM) increased as much as nearly 25 times from 165 to 4220 mg/L as the velocity increased. Heavy metals showed an increase in dissolved phase as the velocity increased due to their desorption from the SPM. Acid-soluble heavy metals increased as the velocity increased, indicating that part of the heavy metals transformed from stable phase to labile phase during resuspension. Heavy metal concentrations in the SPM on volume normalization increased by approximately 2-6 times. However, on the mass weighted basis they decreased, approaching the bulk-sediment contents at high velocity, due to the "particle concentration effect". The distribution coefficients (K D ) of heavy metals were higher at slower velocity during the sediment resuspension, which could be attributed to the decrease of fine particles (silt/clay fraction) during resuspension.heavy metals, sediment resuspension, suspended particulate matters, acid-soluble heavy metals, annular flume Citation:Huang J Z, Ge X P, Yang X F, et al. Remobilization of heavy metals during the resuspension of Liangshui River sediments using an annular flume. Chin Sci Bull, 2012, 57: 35673572,

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“…Nowell and Jumars (1987) recommended that flumes for use in biological experiments should have a width to depth ratio of at least 5 to 1 in order to reproduce realistic boundary layers. In a recent review, Jonsson et al (2006) concluded that the ratio between the width of the flume and the wall boundary layer thickness (δ) is a more important consideration, recommending that flume width should exceed 2δ + k where k is a relevant length scale of the organism under investigation. Similarly, an ecologist aware of the diel activity and light sensitivity of aquatic insects may question the value of examining the movements of negatively phototactic species on flume beds that are brightly lit or lacking shelter (Barmuta et al, 2001).…”

Section: General Considerations For Interdisciplinary Flume Experimentsmentioning

confidence: 99%

“…Jonsson et al, (2006) recently made a direct comparison of a selection of facilities with the aim of identifying those flumes best suited to the study of benthos-flow interactions in marine environments. In general, however, we are unaware of attempts to define facility protocols or best-practice procedures.…”

Section: Flume Facilities and Hydraulic Measurementsmentioning

confidence: 99%

Experimentation at the interface of fluvial geomorphology, stream ecology and hydraulic engineering and the development of an effective, interdisciplinary river science

Rice

Lancaster

Kemp

2009

Earth Surf Processes Landf

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One "2020 vision" for fluvial geomorphology is that it sits alongside stream ecology and hydraulic engineering as a key element of an integrated, interdisciplinary river science. A challenge to this vision is that scientists from these three communities may approach problems from different perspectives with different questions and have different methodological outlooks. Refining interdisciplinary methodology is important in this context, but raises a number of issues for geomorphologists, ecologists and engineers alike. In particular, we believe that it is important that there is greater dialogue about the nature of mutually-valued questions and the adoption of mutually-acceptable methods. As a contribution to this dialogue we examine the benefits and challenges of using physical experimentation in flume laboratories to ask interdisciplinary questions. Working in this arena presents the same challenges that experimental geomorphologists and engineers are familiar with (scaling up results, technical difficulties, realism) and some new ones including recognising the importance of biological processes, identifying hydraulically meaningful biological groups, accommodating the singular behaviour of individuals, understanding biological as well as physical stimuli, and the husbandry and welfare of live organisms. These issues are illustrated using two examples from flume experiments designed (1) to understand how the movement behaviours of aquatic insects through the near-bed flow field of gravelly river beds may allow them to survive flood events, and (2) how an understanding of the way in which fish behaviours and swimming capability are affected by flow conditions around artificial structures can lead to the design of effective fish passages. In each case, an interdisciplinary approach has been of substantial mutual benefit and led to greater insights than discipline-specific work would have produced. Looking forward to 2020, several key challenges for experimentalists working on the interface of fluvial geomorphology, stream ecology and hydraulic engineering are identified.3

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Making water flow: a comparison of the hydrodynamic characteristics of 12 different benthic biological flumes

Cited by 41 publications

References 50 publications

Erosion threshold of saturated natural cohesive sediments: Modeling and experiments

Erosion threshold of saturated natural cohesive sediments: Modeling and experiments

Remobilization of heavy metals during the resuspension of Liangshui River sediments using an annular flume

Experimentation at the interface of fluvial geomorphology, stream ecology and hydraulic engineering and the development of an effective, interdisciplinary river science

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