An experimental study of flow through rigid vegetation

Liu, D.; Diplas, Panayiotis; Fairbanks, Jonathan Dean; Hodges, Clayton

doi:10.1029/2008jf001042

Cited by 183 publications

(205 citation statements)

References 32 publications

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“…In the case of uniform emergent vegetation, reduced current velocities are found to be approximately constant over the water depth, except in the near-bed region where additional bed shear causes a local velocity peak (Liu et al, 2008;Nepf, 1999;Yager and Schmeeckle, 2013). The velocity within emergent vegetation monotonically decreases with the vegetation density (ad = Nd 2 , wherein N is the number of stems per unit area and d the stem diameter), the water depth-to-stem diameter ratio (H/d) and the surface roughness (CD) of the vegetation elements (Liu et al, 2008;Nepf, 1999). The turbulence intensity, expressed as the square-root of the turbulent kinetic energy divided by the flow velocity, k 1/2 /u, is constant over depth outside the bed-shear layer, similar to the velocity profile (Liu et al, 2008).…”

Section: Introductionmentioning

confidence: 97%

“…Mazda and Wolanski, 2009;Nepf, 2012;Tempest et al, 2015). In the case of uniform emergent vegetation, reduced current velocities are found to be approximately constant over the water depth, except in the near-bed region where additional bed shear causes a local velocity peak (Liu et al, 2008;Nepf, 1999;Yager and Schmeeckle, 2013). The velocity within emergent vegetation monotonically decreases with the vegetation density (ad = Nd 2 , wherein N is the number of stems per unit area and d the stem diameter), the water depth-to-stem diameter ratio (H/d) and the surface roughness (CD) of the vegetation elements (Liu et al, 2008;Nepf, 1999).…”

Section: Introductionmentioning

confidence: 99%

“…Above a submerged canopy with height hc, a characteristic logarithmic velocity profile develops for depth ratios H/hc > 1.25 (Liu et al, 2008;Nepf and Vivoni, 2000), with an inflection point close to the top of the canopy. Often Kelvin-Helmholtz vortices are generated in this canopy shear layer, giving rise to a dynamic mixing layer and a local peak in the turbulence profile (Chen et al, 2013;Liu et al, 2008;Raupach et al, 1996).…”

Section: Introductionmentioning

confidence: 99%

“…The velocity within emergent vegetation monotonically decreases with the vegetation density (ad = Nd 2 , wherein N is the number of stems per unit area and d the stem diameter), the water depth-to-stem diameter ratio (H/d) and the surface roughness (CD) of the vegetation elements (Liu et al, 2008;Nepf, 1999). The turbulence intensity, expressed as the square-root of the turbulent kinetic energy divided by the flow velocity, k 1/2 /u, is constant over depth outside the bed-shear layer, similar to the velocity profile (Liu et al, 2008). While turbulence intensity increases with the presence of sparse emergent vegetation, a critical vegetation density exists beyond which the turbulence decreases because of the reduction in velocity with increased density (Nepf, 1999).…”

Section: Introductionmentioning

confidence: 99%

“…Often Kelvin-Helmholtz vortices are generated in this canopy shear layer, giving rise to a dynamic mixing layer and a local peak in the turbulence profile (Chen et al, 2013;Liu et al, 2008;Raupach et al, 1996). As with emergent canopies, the elevation of the logarithmic velocity profile with respect to the top of the submerged vegetation, and consequently the penetration depth of the turbulence into the vegetation, depends on the vegetation density, the relative height of the vegetation (H/hc) and the surface roughness of the vegetation elements (Liu et al, 2008;Lowe et al, 2005;Nepf and Vivoni, 2000).…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Model Versus Nature: Hydrodynamics in Mangrove Pneumatophores

Horstman

Bryan

Mullarney

et al. 2017

Int. Conf. Coastal. Eng.

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Water flows through submerged and emergent vegetation control the transport and deposition of sediment in coastal wetlands. Many past studies into the hydrodynamics of vegetation fields have used idealized vegetation mimics, mostly rigid dowels of uniform height. In this study, a canopy of real mangrove pneumatophores was reconstructed in a flume to quantify flow and turbulence within and above this canopy. At a constant flow forcing, an increase in pneumatophore density, from 71 m -2 to 268 m -2 , was found to cause a reduction of the within-canopy flow velocities, whereas the over-canopy flows increased. Within-canopy velocities reduced to 46% and 27% of the free-stream velocities for the lowest and highest pneumatophore densities, respectively, resulting in stronger vertical shear and hence greater turbulence production around the top of the denser pneumatophore canopies. The maximum Reynolds stress was observed at 1.5 times the average pneumatophore height, in contrast to uniform-height canopies, in which the maximum occurs at approximately the height of the vegetation. The ratios of the within-canopy velocity to the free-stream velocity for the pneumatophores were found to be similar to previous observations with uniform-height vegetation mimics for the same vegetation densities. However, maxima of the scaled friction velocity were two times smaller over the real pneumatophore canopies than for idealized dowel canopies, due to the reduced velocity gradients over the variable-height pneumatophores compared to uniform-height dowels. These findings imply that results from previous studies with idealized and uniform vegetation mimics may have limited application when considering sediment transport and deposition in real vegetation, as the observed turbulence characteristics in nonuniform canopies deviate significantly from those in dowel canopies.

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Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Model Versus Nature: Hydrodynamics in Mangrove Pneumatophores

Horstman

Bryan

Mullarney

et al. 2017

Int. Conf. Coastal. Eng.

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When do plants modify fluvial processes? Plant‐hydraulic interactions under variable flow and sediment supply rates

Manners

Wilcox

et al. 2015

JGR Earth Surface

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Flow and sediment regimes shape alluvial river channels; yet the influence of these abiotic drivers can be strongly mediated by biotic factors such as the size and density of riparian vegetation. We present results from an experiment designed to identify when plants control fluvial processes and to investigate the sensitivity of fluvial processes to changes in plant characteristics versus changes in flow rate or sediment supply. Live seedlings of two species with distinct morphologies, tamarisk (Tamarix spp.) and cottonwood (Populus fremontii), were placed in different configurations in a mobile sand-bed flume. We measured the hydraulic and sediment flux responses of the channel at different flow rates and sediment supply conditions representing equilibrium (sediment supply = transport rate) and deficit (sediment supply < transport rate). We found that the hydraulic and sediment flux responses during sediment equilibrium represented a balance between abiotic and biotic factors and was sensitive to increasing flow rates and plant species and configuration. Species-specific traits controlled the hydraulic response: compared to cottonwood, which has a more tree-like morphology, the shrubby morphology of tamarisk resulted in less pronation and greater reductions in near-bed velocities, Reynolds stress, and sediment flux rates. Under sediment-deficit conditions, on the other hand, abiotic factors dampened the effect of variations in plant characteristics on the hydraulic response. We identified scenarios for which the highest stem-density patch, independent of abiotic factors, dominated the fluvial response. These results provide insight into how and when plants influence fluvial processes in natural systems.

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Estimation of the bed shear stress in vegetated and bare channels with smooth beds

Yang

Kerger

Nepf

2015

Water Resources Research

132

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The shear stress at the bed of a channel influences important benthic processes such as sediment transport. Several methods exist to estimate the bed shear stress in bare channels without vegetation, but most of these are not appropriate for vegetated channels due to the impact of vegetation on the velocity profile and turbulence production. This study proposes a new model to estimate the bed shear stress in both vegetated and bare channels with smooth beds. The model, which is supported by measurements, indicates that for both bare and vegetated channels with smooth beds, within a viscous sublayer at the bed, the viscous stress decreases linearly with increasing distance from the bed, resulting in a parabolic velocity profile at the bed. For bare channels, the model describes the velocity profile in the overlap region of the Law of the Wall. For emergent canopies of sufficient density (frontal area per unit canopy volume a ! 4:3 m 21 ), the thickness of the linear-stress layer is set by the stem diameter, leading to a simple estimate for bed shear stress.

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An experimental study of flow through rigid vegetation

Cited by 183 publications

References 32 publications

Model Versus Nature: Hydrodynamics in Mangrove Pneumatophores

Model Versus Nature: Hydrodynamics in Mangrove Pneumatophores

When do plants modify fluvial processes? Plant‐hydraulic interactions under variable flow and sediment supply rates

Estimation of the bed shear stress in vegetated and bare channels with smooth beds

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