2009
DOI: 10.1029/2008wr006826
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Theoretical development on the effects of changing flow hydraulics on incipient bed load motion

Abstract: [1] Several decades of flume and field measurements have indicated that in rough turbulent flows the critical Shields stress increases with increasing slope and associated decreasing relative depth. This result contradicts the usual consideration of a decreased critical Shields value on very steep slopes because of increased gravitational effects. However, recent studies have demonstrated that these experimental results could be reproduced with a force balance model if the classical logarithmic velocity profil… Show more

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Cited by 180 publications
(260 citation statements)
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References 109 publications
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“…This type of channelised run-off could be a combination of three factors: rainfall, melting ice or the overflow that forms when a glacier collapses downward into a water pool. The mechanism of this process lies in the hydrodynamic forces exerted on the surface elements of debris layers and surpassing sediment resistance (Gregoretti and Dalla Fontana, 2008;Recking et al, 2009;Prancevic et al, 2014). The concentration of run-off in the channel bottom causes the erosion of the debris surface layer, forming a solid-liquid current at first, then extends to the layers below with whole or partial mobilisation and debris flows were generated (Gregoretti and Dalla Fontana, 2008).…”
Section: Failure Of Glacial Tillmentioning
confidence: 99%
“…This type of channelised run-off could be a combination of three factors: rainfall, melting ice or the overflow that forms when a glacier collapses downward into a water pool. The mechanism of this process lies in the hydrodynamic forces exerted on the surface elements of debris layers and surpassing sediment resistance (Gregoretti and Dalla Fontana, 2008;Recking et al, 2009;Prancevic et al, 2014). The concentration of run-off in the channel bottom causes the erosion of the debris surface layer, forming a solid-liquid current at first, then extends to the layers below with whole or partial mobilisation and debris flows were generated (Gregoretti and Dalla Fontana, 2008).…”
Section: Failure Of Glacial Tillmentioning
confidence: 99%
“…The empirical exponent m ranges from 0 to −1, where m = −1 corresponds to the so-called "equal mobility" case in which all grains start moving at the same bed shear stress τ , and m = 0 corresponds to no influence by hiding at all. For x = 50, the values for m, which have been derived from various field observations, typically vary within a range from −0.60 to −1.00 (Recking, 2009), and unfortunately there are only few data points for D i > D 50 (Bathurst, 2013;Bunte et al, 2013). For consistency, the following θ ci,r is used in bedload transport calculations.…”
Section: Flow Resistancementioning
confidence: 99%
“…Bedload prediction is of primary importance for river engineering, fluvial geomorphology, eco-hydrology, environmental surveys and management, and hazard prediction (Recking, 2009). Bedload transport provides the major process linkage between the hydraulic and material conditions that govern river-channel morphology and knowledge of bedload movement is required not only to elucidate the causes and consequences of changes in fluvial form but also to make informed management decisions that affect a river's function.…”
Section: Introductionmentioning
confidence: 99%