Gravel threshold of motion: a state function of sediment transport
disequilibrium?

Johnson, J. P.

doi:10.5194/esurf-4-685-2016

Cited by 41 publications

(60 citation statements)

References 72 publications

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“…Downstream from the dam site, river response to a pulse of reservoir sediment is commonly anticipated to include aggradation, channel widening, filling of riverbed pools, and bed‐sediment fining (Cui et al, ; Downs et al, ; Pizzuto, ), changes generally confirmed by field studies to date (e.g., Major et al, ; Pearson et al, ; Tullos et al, ; Wang & Kuo, ; Wilcox et al, ; Wohl & Cenderelli, ). These geomorphic responses to newly introduced sediment supply might be expected to change the river corridor's sensitivity to discharge, given that aggradation generally increases channel‐floodplain connectivity and that smoothing of bed topography by new deposition can enhance sediment mobility (Johnson, ; Venditti et al, ). However, because few large dams (>10 m tall) have been removed thus far, relatively little is known about the detailed sedimentary and geomorphic response over substantial spatial or temporal scales following a large dam‐removal sediment release (Major et al, ), including subsequent response to flow forcing.…”

Section: Introductionmentioning

confidence: 99%

“…This hypothesis originates from previous observations of stream responses to increased sediment supply, including aggradation, bed instability, and planform alterations, and follows from the premise that newly introduced sediment supply both aggrades the riverbed, allowing flow to spread readily into the floodplain, and, being commonly finer than the preexisting bed, requires lower shear stress to remobilize the newly deposited bed material (e.g., Ashworth et al, ; Hoffman & Gabet, ; Mohrig et al, ; Recking et al, ; Schumm, ; N. D. Smith & Smith, ). As mentioned above, smoothing of bed topography as sediment pulses fill riverbed pools may also result in more efficient sediment transport (Johnson, ), potentially shaping a channel in which greater topographic change occurs for a given discharge during and in the waning phase of a sediment pulse compared to the relatively sediment‐starved condition prior to the pulse. Thus, we reevaluate the concept of threshold stream power necessary to cause geomorphic change, focusing on the potential contributing factor of sediment supply.…”

Section: Introductionmentioning

confidence: 99%

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Geomorphic Evolution of a Gravel‐Bed River Under Sediment‐Starved Versus Sediment‐Rich Conditions: River Response to the World's Largest Dam Removal

et al. 2018

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Understanding river response to sediment pulses is a fundamental problem in geomorphic process studies, with myriad implications for river management. However, because large sediment pulses are rare and usually unanticipated, they are seldom studied at field scale. We examine fluvial response to a massive (~20 Mt) sediment pulse released by the largest dam removal globally, on the Elwha River, Washington, United States, in an 11‐year before‐after/control‐impact study of channel morphology and grain size. We test the hypothesis that for a given flow magnitude, greater geomorphic change occurs under sediment‐rich conditions than under sediment‐starved conditions. Channel response to flow forcing was significantly different during the sediment‐pulse peak, 1–2 years after dam removal began, than earlier or later. During peak sediment supply our hypothesis was supported; major geomorphic change occurred under low flows and unit stream power ≤60 W/m2. However, by 4–6 years after dam removal began, rates of geomorphic change and sensitivity to stream power had decreased substantially such that our hypothesis was no longer unequivocally supported. These findings are consistent with a two‐phase conceptual model of dam‐removal response, involving a transport‐limited state followed by a more supply‐limited state. From comparisons with other dam removals and natural sediment pulses, we infer that the longevity of sediment‐pulse signals in gravel‐bed rivers depends upon gradient, river discharge, valley morphology, and sediment grain size. Stream power associated with substantial geomorphic change varies with sediment supply, such that assigning a general threshold stream power to gravel‐bed rivers may be untenable.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Geomorphic Evolution of a Gravel‐Bed River Under Sediment‐Starved Versus Sediment‐Rich Conditions: River Response to the World's Largest Dam Removal

et al. 2018

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“…SPACE does not contain independent descriptions of the roughness of bedrock and sediment, and does not distinguish between the case in which bedrock is rougher than sediment and the one in which sediment is rougher than bedrock (e.g., Inoue et al, 2014;Johnson, 2014). We also do not model the potential driving of bedrock erosion by bed load sediment (the tools effect), as used by Sklar and Dietrich (2004), Chatanantavet and Parker (2009), Turowski (2009), Inoue et al (2014, 2016, Zhang et al (2015), and other saltation-abrasion-type models. Both width dynamics and bed load abrasion could be incorporated without changing the underlying model structure but have been omitted in order to facilitate numerical model comparison to analytical solutions.…”

Section: The Space Modelmentioning

confidence: 99%

“…Using a distribution of entrainment thresholds helps to account for the observation that incipient sediment motion does not begin at the same threshold value for all particles (e.g., Buffington and Montgomery, 1997). Variability in the threshold for motion is thought to be a function of grain size and shape variations (Kirchner et al, 1990;Wilcock and McArdell, 1997;Prancevic and Lamb, 2015), grain hiding and protrusion effects (Kirchner et al, 1990;Parker, 1990;Wilcock and McArdell, 1997;McEwan and Heald, 2001), bed sorting (Nelson et al, 2009), sediment flux (Johnson, 2016), and flow history (Masteller and Finnegan, 2017). Similarly, the threshold for bedrock erosion can depend on subreach-scale mineralogy, joint spacing and orientation, and the weathered state of the bedrock.…”

Section: Optional Smoothing Of Entrainment/erosion Thresholdsmentioning

confidence: 99%

The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution

2017

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Abstract. Models of landscape evolution by river erosion are often either transport-limited (sediment is always available but may or may not be transportable) or detachmentlimited (sediment must be detached from the bed but is then always transportable). While several models incorporate elements of, or transition between, transport-limited and detachment-limited behavior, most require that either sediment or bedrock, but not both, are eroded at any given time. Modeling landscape evolution over large spatial and temporal scales requires a model that can (1) transition freely between transport-limited and detachment-limited behavior, (2) simultaneously treat sediment transport and bedrock erosion, and (3) run in 2-D over large grids and be coupled with other surface process models. We present SPACE (stream power with alluvium conservation and entrainment) 1.0, a new model for simultaneous evolution of an alluvium layer and a bedrock bed based on conservation of sediment mass both on the bed and in the water column. The model treats sediment transport and bedrock erosion simultaneously, embracing the reality that many rivers (even those commonly defined as "bedrock" rivers) flow over a partially alluviated bed. SPACE improves on previous models of bedrockalluvial rivers by explicitly calculating sediment erosion and deposition rather than relying on a flux-divergence (Exner) approach. The SPACE model is a component of the Landlab modeling toolkit, a Python-language library used to create models of Earth surface processes. Landlab allows efficient coupling between the SPACE model and components simulating basin hydrology, hillslope evolution, weathering, lithospheric flexure, and other surface processes. Here, we first derive the governing equations of the SPACE model from existing sediment transport and bedrock erosion formulations and explore the behavior of local analytical solutions for sediment flux and alluvium thickness. We derive steadystate analytical solutions for channel slope, alluvium thickness, and sediment flux, and show that SPACE matches predicted behavior in detachment-limited, transport-limited, and mixed conditions. We provide an example of landscape evolution modeling in which SPACE is coupled with hillslope diffusion, and demonstrate that SPACE provides an effective framework for simultaneously modeling 2-D sediment transport and bedrock erosion.

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“…This approach was not possible for the experiments, as the clear water depth was highly variable 10 and not measurable due to the shallow flow over the changing sediment deposits. As an alternative, a relationship for the equilibrium slope was applied, as proposed by (Johnson, 2016): …”

Section: Sediment Depositionmentioning

confidence: 99%

Experimental study of sediment traps permeable for frequent floods

Schwindt

Franca

Reffo

et al. 2017

Preprint

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Abstract. Sediment traps created by partially open torrential barriers are crucial elements for flood protection in alpine regions. 10The trapping of sediment is necessary when intense sediment transport occurs during floods that may endanger urban areas at downstream river reaches. In turn, the unwanted permanent trapping of sediment during small, non-hazardous floods can result in the ecological and morphological depletion of downstream reaches. This study experimentally analyses a new concept for permeable sediment traps. For ensuring the sediment transfer up to small floods, a guiding channel implemented in the deposition area of the sediment trap was studied systematically. The bankfull discharge of the guiding channel corresponds to 15 a dominant morphological discharge. At the downstream end of the guiding channel, a permeable barrier triggers sediment retention and deposition. The permeable barrier consists of a bar screen for mechanical deposition control, superposed to a flow constriction for the hydraulic control. The fail-safe clogging of the barrier and the sediment deposition upstream can be ensured for discharges that are higher than the bankfull discharge of the guiding channel.

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Gravel threshold of motion: a state function of sediment transport disequilibrium?

Cited by 41 publications

References 72 publications

Geomorphic Evolution of a Gravel‐Bed River Under Sediment‐Starved Versus Sediment‐Rich Conditions: River Response to the World's Largest Dam Removal

Geomorphic Evolution of a Gravel‐Bed River Under Sediment‐Starved Versus Sediment‐Rich Conditions: River Response to the World's Largest Dam Removal

The SPACE 1.0 model: a Landlab component for 2-D calculation of sediment transport, bedrock erosion, and landscape evolution

Experimental study of sediment traps permeable for frequent floods

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