Morphodynamics of a bedrock‐alluvial meander bend that incises as it migrates outward: approximate solution of permanent form

Inoue, Takuya; Parker, Gary; Stark, C. P.

doi:10.1002/esp.4094

Cited by 59 publications

(91 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Lague (2010) and Zhang et al (2015) followed a similar approach, further modifying the sediment mass conservation framework to include below-capacity sediment transport. Exner sediment transport in bedrock-alluvial systems was expanded to 2-D by Nelson and Seminara (2012) and Inoue et al (2016Inoue et al ( , 2017, though the specifics of calculating sediment flux differ between the model of Nelson and Seminara (2012) and the latter two. The Exner-based conservation framework allows calculation of bed cover by sediment as a function of the ratio of sediment flux to transport capacity (q s /q c ) (Inoue et al, 2014).…”

Section: Approaches To Mass Conservationmentioning

confidence: 99%

“…Fowler et al (2007) incorporated an equation for bed abrasion by bed load, assuming that abrasion rates should scale with the velocity of the bed load layer and should decline with increasing bed load layer thickness (yielding a form of the tools and cover effects). Several workers have adapted forms of the saltationabrasion bedrock erosion model of Dietrich (1998, 2004) in conjunction with sediment mass conservation to incorporate both the tools and cover effects into models of bedrock-alluvial river erosion (Turowski, 2009;Nelson and Seminara, 2011;Inoue et al, 2014Inoue et al, , 2016Inoue et al, , 2017. Turowski (2009) combined a stochastic erosion-deposition model with a saltation-abrasion-style incision rule and explored the sensitivity of bed cover and bedrock erosion rate to changes in sediment transport.…”

Section: Coupled Sediment Transport and Bedrock Erosion Modelsmentioning

confidence: 99%

“…They used a modified Exner equation for sediment mass conservation incorporating both mobile bed load and an alluvial layer, and a saltation-abrasion-style bedrock incision rule (Sklar and Dietrich, 2004;Chatanantavet and Parker, 2009). Inoue et al (2016Inoue et al ( , 2017 expanded the sediment conservation and bedrock erosion formulations of Inoue et al (2014) to 2-D to allow spatial variability in alluvial thickness and bedrock erosion along both the channel length and width. Inoue et al (2017) advanced the model of Inoue et al (2016) by incorporating a simple parameterization for bedrock bank erosion to investigate meander bend migration.…”

Section: Coupled Sediment Transport and Bedrock Erosion Modelsmentioning

confidence: 99%

See 2 more Smart Citations

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

2017

View full text Add to dashboard Cite

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.

show abstract

Section: Approaches To Mass Conservationmentioning

confidence: 99%

Section: Coupled Sediment Transport and Bedrock Erosion Modelsmentioning

confidence: 99%

Section: Coupled Sediment Transport and Bedrock Erosion Modelsmentioning

confidence: 99%

See 1 more Smart Citation

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

2017

View full text Add to dashboard Cite

show abstract

“…Following this line, most of the models which address the morphological evolution of the rivers couple hydrodynamic and bed evolution submodels with a bank erosion submodel, so they are able to predict changes in both bed and bank form, comprehending also bank failure (e.g., [28][29][30][31][32][33][34][35][36][37]). Nevertheless, their approach can differ significantly from one another.…”

Section: Introductionmentioning

confidence: 99%

“…Some authors, for example, conduct a proper bank stability investigation, considering a limit equilibrium analysis for planar or rotational slip failure [29,30] or a cantilever failure [30]. Others evaluate a bank erosion/accretion rate, which gives rise to the displacement of bank top and a consequent mesh modification [31,32,[35][36][37] or, in a similar way, they couple a bed scouring with an intermittent bank erosion model, which shift the bank while keeping the same initial angle of repose [28]. Another approach consists in coupling the basal erosion due to hydrodynamic forces with a bank failure model, which triggers when the bank slope exceeds a critical angle [33,34,38,39].…”

Section: Introductionmentioning

confidence: 99%

Numerical Modelling of Cohesive Bank Migration

Bosa

Petti

Pascolo

2018

Water

View full text Add to dashboard Cite

River morphological evolution is a challenging topic, involving hydrodynamic flow, sediment transport and bank stability. Lowland rivers are often characterized by the coexistence of granular and cohesive material, with significantly different behaviours. This paper presents a bidimensional morphological model to describe the evolution of the lower course of rivers, where there are both granular and cohesive sediments. The hydrodynamic equations are coupled with two advection-diffusion equations, which consider the transport of granular and cohesive suspended sediment concentration separately. The change of bed height is evaluated as the sum of the contributions of granular and sediment material. A bank failure criterion is developed and incorporated into the numerical simulation of the hydrodynamic flood wave and channel evolution, to describe both bed deformation and bank recession. To this aim, two particular mechanisms are considered: the former being a lateral erosion due to the current flow and consequent cantilever collapse and the latter a geostatic failure due to the submergence. The equation system is integrated by means of a finite volume scheme. The resulting model is applied to the Tagliamento River, in northern Italy, where the meander migration is documented through a sequence of aerial images. The channel evolution is simulated, imposing an equivalent hydrograph consisting of a sequence of flood waves, which represents a medium year, with reference to their effect on sediment transport. The results show that the model adequately describes the general morphological evolution of the meander.

show abstract

Hydro‐sedimentological processes in meandering rivers

Blanckaert

2018

Fluvial Meanders and Their Sedimentary Products in the Rock Record

View full text Add to dashboard Cite

Morphodynamics of a bedrock‐alluvial meander bend that incises as it migrates outward: approximate solution of permanent form

Cited by 59 publications

References 43 publications

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

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

Numerical Modelling of Cohesive Bank Migration

Hydro‐sedimentological processes in meandering rivers

Contact Info

Product

Resources

About