Steady nonuniform shallow flow within emergent vegetation

Wang, Wei-Jie; Huai, Wenxin; Thompson, Sally; Katul, Gabriel G.

doi:10.1002/2015wr017658

Cited by 45 publications

(76 citation statements)

References 59 publications

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“…They suggested that drag coefficient must be varying along vegetation length in stream-wise direction. Their finding illustrated that C d (x)/< C d > increases and then decreases with increasing distant from flume inlet forming a hump-shape that has been studied elsewhere [28]. The drag coefficient for dense vegetation differs from that of single vegetation of the same form.…”

Section: Introductionmentioning

confidence: 62%

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Effect of submerged vegetation density on flow under favorable pressure gradient

Brahimi

Afzalimehr

2018

SN Appl. Sci.

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Section: Introductionmentioning

confidence: 62%

“…Most of the studies used solid circular cylinders in regular rows for quantifying the impact of vegetation on flow characteristics and drag coefficient [28][29][30][31][32][33]. However, cylinders do not adequately represent vegetation because of the differences in flexibility, roughness, shape, etc.…”

Section: Introductionmentioning

confidence: 99%

Effect of submerged vegetation density on flow under favorable pressure gradient

Brahimi

Afzalimehr

2018

SN Appl. Sci.

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“…Indeed, overland flow of water during intense rainfall events on semi-arid flat plains is the subject of ongoing research (e.g. [89,96,72]). A detailed description of the overland water flow and infiltration into the soil that occurs before water is consumed by plants relies on a clear distinction between the surface water density and the soil moisture.…”

Section: Discussionmentioning

confidence: 99%

Effects of precipitation intermittency on vegetation patterns in semi-arid landscapes

Eigentler

Sherratt

2020

Physica D: Nonlinear Phenomena

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Patterns of vegetation are a characteristic feature of many semi-arid regions. The limiting resource in these ecosystems is water, which is added to the system through short and intense rainfall events that cause a pulse of biological processes such as plant growth and seed dispersal. We propose an impulsive model based on the Klausmeier reaction-advection-diffusion system, analytically investigate the effects of rainfall intermittency on the onset of patterns, and augment our results by numerical simulations of model extensions. Our investigation focuses on the parameter region in which a transition between uniform and patterned vegetation occurs. Results show that decay-type processes associated with a low frequency of precipitation pulses inhibit the onset of patterns and that under intermittent rainfall regimes, a spatially uniform solution is sustained at lower total precipitation volumes than under continuous rainfall, if plant species are unable to efficiently use low soil moisture levels. Unlike in the classical setting of a reaction-diffusion model, patterns are not caused by a diffusion-driven instability but by a combination of sufficiently long periods of droughts between precipitation pulses and water diffusion. Our results further indicate that the introduction of pulse-type seed dispersal weakens the effects of changes to width and shape of the plant dispersal kernel on the onset of patterns. MSC codes: 35R09, 35R12, 35B36

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“…For an isolated cylinder, the local C d (labeled as C d ,iso ) can be determined from the bulk velocity and rod diameter by forming an element Reynolds number Re d = UD / ν . An approximate expression for C d ,iso that describes data for isolated cylinders and for Re d < 10 5 is given by (Cheng, ; Wang et al, )

C_{d, iso} = 11 {false(R e_{d} false)}^{- 0.75} + 0.9 Γ_{1} ((), {R e}_{d}) + 1.2 Γ_{2} ((), {R e}_{d}),

where

Γ_{1} ((), {R e}_{d}) = 1 - \exp ((), - \frac{1000}{{R e}_{d}})

and

Γ_{2} ((), {R e}_{d}) = 1 - \exp ([], - {((), \frac{{R e}_{d}}{4500})}^{0.7}) .

…”

Section: Theorymentioning

confidence: 99%

“…A number of formulations have been proposed to link S f to vegetation drag coefficient C d assuming a steady uniform flow. These formulations, or variants on them, have been shown to capture blockage, sheltering, angle of separation, among others (Baptist et al, ; Carollo et al, ; Chapman et al, ; Cheng, ; Cheng & Nguyen, ; Dijkstra & Uittenbogaard, ; Etminan et al, ; James et al, ; Järvelä, ; Kouwen et al, ; Kim et al, ; Konings et al, ; Tanino & Nepf, ; Wang et al, , ; Zhao et al, ). However, the dam break problem leads to transient surface waves (Kobayashi et al, ) as well as large horizontal gradients in Froude numbers (Ishikawa et al, ) not present in conventional uniform canopy flow studies.…”

Section: Introductionmentioning

confidence: 99%

Resistance to Flow on a Sloping Channel Covered by Dense Vegetation following a Dam Break

Melis

Poggi

Giovanni

et al. 2019

Water Resources Research

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The effect of hydraulic resistance on the downstream evolution of the water surface profile h in a sloping channel covered by a uniform dense rod canopy following the instantaneous collapse of a dam was examined using flume experiments. Near the head of the advancing wavefront, where h meets the rods, the conventional picture of a turbulent boundary layer was contrasted to a distributed drag force representation. The details of the boundary layer around the rod and any interferences between rods were lumped into a drag coefficient C d . The study demonstrated the following: In the absence of a canopy, the Ritter solution agreed well with the measurements. When the canopy was represented by an equivalent wall friction as common when employing Manning's formula with constant roughness, it was possible to match the measured wavefront speed but not the precise shape of the water surface profile. However, upon adopting a distributed drag force with a constant C d , the agreement between measured and modeled h was quite satisfactory at all positions and times. The measurements and model calculations suggested that the shape of h near the wavefront was quasilinear with longitudinal distance for a constant C d . The computed constant C d (≈0.4) was surprisingly much smaller than the C d (≈1) reported in uniform flow experiments with staggered cylinders for the same element Reynolds number. This finding suggested that drag reduction mechanisms associated with unsteadiness, nonuniformity, transient waves, and other flow disturbances were more likely to play a role when compared to conventional sheltering effects.After a dam break, the flow is generally approximated by the Saint-Venant equation (SVE) derived from the Navier-Stokes equations assuming (i) constant water density, (ii) that the water depth h is small compared with other length scales such as the wave length of the water surface or the channel width, (iii) that the pressure distribution is approximately hydrostatic so that vertical acceleration can be ignored, and (iv) that the bed slope is not too steep (de Saint-Venant, 1871). For these conditions, the continuity equation and SVE for a rectangular prismatic section of width B after a dam break are given by (French, 1985;Lighthill &

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Steady nonuniform shallow flow within emergent vegetation

Cited by 45 publications

References 59 publications

Effect of submerged vegetation density on flow under favorable pressure gradient

Effect of submerged vegetation density on flow under favorable pressure gradient

Effects of precipitation intermittency on vegetation patterns in semi-arid landscapes

Resistance to Flow on a Sloping Channel Covered by Dense Vegetation following a Dam Break

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