Hydraulic properties affected by litter and stem cover under overland flow

Ding, Lin; Fu, Suhua; Zhao, Hui

doi:10.1002/hyp.14088

Cited by 7 publications

(2 citation statements)

References 44 publications

(112 reference statements)

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“…Ding and Li (2016) also found that there was little difference in Re on slopes with different grass cover, and identified that Re increased with the rise of discharge. Ding et al (2021) reached a similar conclusion. found no obvious trend between Re and the amount of litter after having conducted experimental tests simulating rainfall on a slope covered by litter.…”

supporting

confidence: 61%

Experimental study on the effect of simulated grass and stem coverage on resistance coefficient of overland flow

Cen

Zhang

Peng

et al. 2022

Hydrological Processes

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Vegetation plays a significant role in preventing desertification, conservation of soil and water. However, nowadays, there is still uncertainty regarding the mechanisms of flow resistance caused by dissimilar vegetation covers. To address this gap, a series of these was conducted in this study to investigate the influence of synthetic grass and stems on the variation of resistance on overland flows. Thirty vegetation configurations were selected (combining five synthetic grass coverage options and six synthetic stem coverage ones), and tested against five unit discharges (flow range = 0.28–2.22 L m−1 s−1) and four slope gradients (3.49%–20.78%). The results obtained showed that the unit discharge is the key driving factor for the transition from laminar to transitional flow. Furthermore, the relationship between the resistance coefficient (f) and the Reynolds number (Re) was not monotonically increasing or decreasing, but behaviours observed were specifically linked to each vegetation coverage. However, a critical coverage threshold was identified, and it corresponded to 2.72% when the slope gradient tested was 3.49%. This threshold decreased with the increase of the slope gradient. In addition, when the vegetation coverage was less than the critical threshold, the f was negatively correlated with Re, otherwise if the vegetation coverage was higher than the critical threshold identified the f–Re relation was positively correlated. The total flow resistance under synthetic grass and stem cover was unequal to the linear superposition of grain resistance and form resistance caused by synthetic stem and grass, which meant that the linear superposition approach is not applicable to overland flows. Finally, a model was developed to predict the flow resistance by applying the π‐theorem and the multiple nonlinear regression analysis and it has been validated against the experimental results confirming its accuracy and high performance (adj.R2 = 0.99, NSE = 0.94).

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confidence: 61%

Experimental study on the effect of simulated grass and stem coverage on resistance coefficient of overland flow

Cen

Zhang

Peng

et al. 2022

Hydrological Processes

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“…A newer formulation describing depth-dependent roughness based on the Manning equation has been provided by Fu et al (2019). Later the equation has been adapted to be valid for litter cover (Ding et al, 2021). Fu conducted several laboratory experiments for a vegetation cover from 0 to 30% with artificial plants with a height of 12 cm.…”

Section: Fu's Equationmentioning

confidence: 99%

Near surface roughness estimation: A parameterization derived from artificial rainfall experiments and two-dimensional hydrodynamic modelling for multiple vegetation coverages

Feldmann

Laux

Heckl

et al. 2023

Journal of Hydrology

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Sediment transport capacity as affected by different combinations of vegetation litter and stem cover

Ding

2022

CATENA

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Hydraulic properties affected by litter and stem cover under overland flow

Cited by 7 publications

References 44 publications

Experimental study on the effect of simulated grass and stem coverage on resistance coefficient of overland flow

Experimental study on the effect of simulated grass and stem coverage on resistance coefficient of overland flow

Near surface roughness estimation: A parameterization derived from artificial rainfall experiments and two-dimensional hydrodynamic modelling for multiple vegetation coverages

Sediment transport capacity as affected by different combinations of vegetation litter and stem cover

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