Experimental Insights Into the Threshold of Motion in Alluvial Channels: Sediment Supply and Streambed State

Hassan, Marwan A.; Saletti, Matteo; Johnson, J. P.; Ferrer‐Boix, Carles; Venditti, Jeremy G.; Church, Michael

doi:10.1029/2020jf005736

Cited by 26 publications

(30 citation statements)

References 72 publications

(203 reference statements)

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“…Previous researchers (Haynes and Pender, 2007;Masteller and Finnegan, 2017) have suggested that an exponential function can be implemented to describe such a decrease of sediment transport rate under conditioning flow. Additional analysis is implemented in the Supplement to fit REF2 (15) and REF6 (15) (which have the longest duration of conditioning phase) against a two-parameter exponential function.…”

Section: Sediment Transportmentioning

confidence: 99%

“…To further study such "memory" effects of antecedent flow on the sediment transport during a subsequent flood, a number of flume experiments and field surveys have been conducted in the past decade, and different terms have been proposed, including "stress history effect" (Monteith and Pender, 2005;Paphitis and Collins, 2005;Haynes and Pender, 2007;Ockelford and Haynes, 2013), "flood history effect" (Mao, 2018), and "flow history" (Masteller et al, 2019). The difference in the terminology could be partly due to the available data and the chosen approach in different research works.…”

Section: Introductionmentioning

confidence: 99%

“…They found that with a longer and higher antecedent flow, the critical bed shear stress increases and the total bed load flux decreases. The work of Paphitis and Collins (2005) was extended by Monteith and Pender (2005) and Haynes and Pender (2007) to consider bimodal sand-gravel mixtures. They found that for a graded bed, longer periods of antecedent flow increase bed stability due to local particle rearrangement, in agreement with Paphitis and Collins (2005), whereas higher magnitudes of antecedent flow reduce bed stability due to selective entrainment of the fine matrix on bed surface, counter to Paphitis and Collins' (2005) conclusion based on uniform sediment.…”

Section: Introductionmentioning

confidence: 99%

“…They found that for a graded bed, longer periods of antecedent flow increase bed stability due to local particle rearrangement, in agreement with Paphitis and Collins (2005), whereas higher magnitudes of antecedent flow reduce bed stability due to selective entrainment of the fine matrix on bed surface, counter to Paphitis and Collins' (2005) conclusion based on uniform sediment. Haynes and Pender (2007) further analyzed the two competing effects and concluded that particle rearrangement may be of greater relative importance than the winnowing of the fine sediment, as it affects subsequent sediment transport. By using high-resolution laser scanning and statistical analysis of the bed topography, Ockelford and Haynes (2013) also demonstrated that the response of bed topography to stress history is grade-specific: bed roughness decreased in uniform beds but increased in graded beds with an increase length of an antecedent flow period.…”

Section: Introductionmentioning

confidence: 99%

“…Research to date has shown that antecedent flow can stabilize the river bed, thus influencing the threshold of sediment motion and bed load flux. However, most of the previous research about stress history is either under conditions with relatively low sediment transport or with relatively short durations of sediment transport in order to capture the threshold of sediment motion (Monteith and Pender, 2005;Paphitis and Collins, 2005;Haynes and Pender, 2007;Ockelford and Haynes, 2013;Masteller and Finnegan, 2017;Ockelford et al, 2019). On the other hand, other researchers have found that exceptionally high-discharge events can reduce critical shear stress by disrupting particle interlocking and breaking of bed structure (Lenzi, 2001;Turowski et al, 2009Turowski et al, , 2011Yager et al, 2012;Ferrer-Boix and Hassan, 2015;Masteller et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Effect of stress history on sediment transport and channel adjustment in graded gravel-bed rivers

Hassan

Ferrer‐Boix

et al. 2021

Earth Surf. Dynam.

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Abstract. With the increasing attention on environmental flow management for the maintenance of habitat diversity and ecosystem health of mountain gravel-bed rivers, much interest has been paid to how inter-flood low flow can affect gravel-bed river morphodynamics during subsequent flood events. Previous research has found that antecedent conditioning flow can lead to an increase in critical shear stress and a reduction in sediment transport rate during a subsequent flood. However, how long this effect can last during the flood event has not been fully discussed. In this paper, a series of flume experiments with various durations of conditioning flow are presented to study this problem. Results show that channel morphology adjusts significantly within the first 15 min of the conditioning flow but becomes rather stable during the remainder of the conditioning flow. The implementation of conditioning flow can indeed lead to a reduction of sediment transport rate during the subsequent hydrograph, but such an effect is limited to within a relatively short time at the beginning of the hydrograph. This indicates that bed reorganization during the conditioning phase, which induces the stress history effect, is likely to be erased with increasing intensity of flow and sediment transport during the subsequent flood event.

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Section: Sediment Transportmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Effect of stress history on sediment transport and channel adjustment in graded gravel-bed rivers

Hassan

Ferrer‐Boix

et al. 2021

Earth Surf. Dynam.

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Experimental insights into the effect of event sequencing and sediment input texture on step‐pool channel evolution

Wang

Hassan

Saletti

et al. 2021

Earth Surf Processes Landf

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We conducted flume experiments in a step‐pool channel with different sediment supply regimes to explore how the sequencing and the grain‐size of sediment pulses affect channel evolution. Our results show that the sequencing of events is not a primary control as the trends in flow characteristics, bedload transport, sediment storage, step evolution, and step frequency were similar in feed phases with different sequencing of sediment pulses. Channel adjustment and step stability in a short timescale (i.e., in a 4‐h run) were mostly controlled by the magnitude and frequency of sediment pulses. A coarser sediment feed mixture led to a coarser bed surface which increased both sediment storage in the channel and step stability. Our experiments show that channel evolution in a step‐pool channel is primarily controlled by the magnitude and frequency of sediment pulses and the grain size of sediment supply rather than the event sequencing of sediment pulses.

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The influence of bedrock river morphology and alluvial cover on gravel entrainment. Part 2: Modelling critical shear stress

Hodge

Buechel

2022

Earth Surf Processes Landf

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The critical shear stress (τ c ) at which grains are entrained on a bedrock surface is important for determining how bedrock rivers evolve through changes in sediment cover and bedrock erosion. The difference in τ c for grains on bedrock and alluvial surfaces also determines whether a channel may be susceptible to runaway alluviation.Bedrock channel beds can have a wide variety of morphologies, but we do not fully understand how this variation affects τ c . Here we address how bedrock morphology alters the grain entrainment parameters of pivoting angle, grain exposure and roughness height z 0 , and thus τ c . In our companion article we used scaled, 3D printed replicas of seven bedrock surfaces to measure grain pivoting angles for four grain sizes.For three surfaces, pivoting angles were also measured with 25-100% sediment cover. In this second article, we combine these pivot angle data with measurements of grain exposure and surface roughness (standard deviation of elevations, σ z ) to predict τ c using a force-balance model. The bedrock topography produces substantial variation in τ c ; for a given grain diameter (D), a 3.6Â range of σ z across the surfaces without sediment cover produces up to a 5.1Â variation in τ c . For comparison, for any single surface, τ c varies by up to 2.5Â for a fourfold range in grain size. Comparison to previous models with less representation of grain-scale geometry shows that in our results grains move at lower values of dimensionless critical shear stress (τ* c ), and that τ* c decreases more quickly with increasing D/σ z . However, direct comparison is difficult because previous relationships are based on a hydraulic roughness length that cannot be easily predicted without hydraulic data. Our results propose a new relationship between D/σ z and τ* c , but further development and testing require datasets that combine measurements of flow, τ c and grain-scale geometry.

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Experimental Insights Into the Threshold of Motion in Alluvial Channels: Sediment Supply and Streambed State

Cited by 26 publications

References 72 publications

Effect of stress history on sediment transport and channel adjustment in graded gravel-bed rivers

Effect of stress history on sediment transport and channel adjustment in graded gravel-bed rivers

Experimental insights into the effect of event sequencing and sediment input texture on step‐pool channel evolution

The influence of bedrock river morphology and alluvial cover on gravel entrainment. Part 2: Modelling critical shear stress

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