Vegetated mixing layer around a finite‐size patch of submerged plants: 1. Theory and field experiments

Sukhodolova, Tatiana A.; Sukhodolov, Alexander N.

doi:10.1029/2011wr011804

Cited by 57 publications

(49 citation statements)

References 43 publications

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“…Following Sukhodolova and Sukhodolov (2012), a value of 0.09 has been used here. The change in vortex thickness through time, as measured using the Q and λ 2 criterion (Fig.…”

Section: Preliminary Resultsmentioning

confidence: 99%

High-resolution numerical modelling of flow—vegetation interactions

Marjoribanks

Hardy

Lane

et al. 2014

Journal of Hydraulic Research

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The full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. data shows good agreement and demonstrates that for a given stem density, the models are able to simulate the extraction of energy from the mean flow at the stem-scale which leads to the drag discontinuity and associated mixing layer.

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“…Following Sukhodolova and Sukhodolov (2012), a value of 0.09 has been used here. The change in vortex thickness through time, as measured using the Q and λ 2 criterion (Fig.…”

Section: Preliminary Resultsmentioning

confidence: 99%

High-resolution numerical modelling of flow—vegetation interactions

Marjoribanks

Hardy

Lane

et al. 2014

Journal of Hydraulic Research

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“…As a consequence of the 2D model approach, it is not possible to derive the stream velocities in and above the vegetation separately. Also, detailed 3D processes are expected to occur around finite submerged vegetation patches [15,64]; vertical circulation patterns and expansion of mixing layers are, however, not captured by the presented 2D model. Skimming flow results in flow separation within and above the canopy, with reduce flow within the canopy and a boundary layer developing above the canopy [65].…”

Section: Discussionmentioning

confidence: 99%

Resistance and reconfiguration of natural flexible submerged vegetation in hydrodynamic river modelling

et al. 2015

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In-stream submerged macrophytes have a complex morphology and several species are not rigid, but are flexible and reconfigure along with the major flow direction to avoid potential damage at high stream velocities. However, in numerical hydrodynamic models, they are often simplified to rigid sticks. In this study hydraulic resistance of vegetation is represented by an adapted bottom friction coefficient and is calculated using an existing two layer formulation for which the input parameters were adjusted to account for (i) the temporary reconfiguration based on an empirical relationship between deflected vegetation height and upstream depth-averaged velocity, and (ii) the complex morphology of natural, flexible, submerged macrophytes. The main advantage of this approach is that it removes the need for calibration of the vegetation resistance coefficient. The calculated hydraulic roughness is an input of the hydrodynamic model Telemac 2D, this model simulates depth-averaged stream velocities in and around individual vegetation patches. Firstly, the model was successfully validated against observed data of a laboratory flume experiment with three macrophyte species at three discharges. Secondly, the effect of reconfiguration was tested by modelling an in situ field flume experiment with, and without, the inclusion of macrophyte reconfiguration. The inclusion of reconfiguration decreased the calculated hydraulic roughness which resulted in smaller spatial variations of simulated stream velocities, as compared to the model scenario without macrophyte reconfiguration. We discuss that including macrophyte reconfiguration in numerical models input, can have significant and extensive effects on the model results of hydrodynamic variables and associated ecological and geomorphological parameters.& Veerle Verschoren

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“…The size of the eddies generated by individual boundary protuberances scales, typically, with the dimension of the protruding elements. Examples of boundary singularities and irregularities in rivers causing eddy generation include sediment clusters or boulders protruding from the riverbed [submerged (Buffin-Bélanger and Roy 1998;Buffin-Bélanger et al 2000;Franca 2005b) or emerging (Tritico and Hotchkiss 2005)], high relative roughness riverbeds (Baiamonte et al 1995;Katul et al 2008), vegetation patches (Tanino and Nepf 2008;Siniscalchi et al 2012;Sukhodolova and Sukhodolov 2012;Ricardo 2014), wood debris or remains of organic elements (Shields et al 2004;Blanckaert et al 2014).…”

Section: Energy-based Description Of Processesmentioning

confidence: 99%

Turbulence in Rivers

Franca

Brocchini

2015

Rivers – Physical, Fluvial and Environmental Processes

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The study of turbulence has always been a challenge for scientists working on geophysical flows. Turbulent flows are common in nature and have an important role in geophysical disciplines such as river morphology, landscape modeling, atmospheric dynamics and ocean currents. At present, new measurement and observation techniques suitable for fieldwork can be combined with laboratory and theoretical work to advance the understanding of river processes. Nevertheless, despite more than a century of attempts to correctly formalize turbulent flows, much still remains to be done by researchers and engineers working in hydraulics and fluid mechanics. In this contribution we introduce a general framework for the analysis of river turbulence. We revisit some findings and theoretical frameworks and provide a critical analysis of where the study of turbulence is important and how to include detailed information of this in the analysis of fluvial processes. We also provide a perspective of some general aspects that are essential for researchers/ practitioners addressing the subject for the first time. Furthermore, we show some results of interest to scientists and engineers working on river flows.

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Vegetated mixing layer around a finite‐size patch of submerged plants: 1. Theory and field experiments

Cited by 57 publications

References 43 publications

High-resolution numerical modelling of flow—vegetation interactions

High-resolution numerical modelling of flow—vegetation interactions

Resistance and reconfiguration of natural flexible submerged vegetation in hydrodynamic river modelling

Turbulence in Rivers

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