Morphodynamics of alternate bars in the presence of riparian vegetation

Jourdain, Camille; Claude, Nicolas; Tassi, Pablo; Cordier, Florian; Antoine, Germain

doi:10.1002/esp.4776

Cited by 35 publications

(36 citation statements)

References 104 publications

(251 reference statements)

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“…Such balance can vary following a reduction in frequency and magnitude of floods, but also by biotic factors such as the arrival of invasive species with better survival ability and colonisation strategies than native species 54 . Previous modelling studies on alternate bars have shown the role played by flow variability and vegetation characteristics in modulating the transition between vegetated and bare states 33,34,55 , indicating the presence of two stable alternative states on alternate bars, steady-vegetated bars and migrating bare bars. Our results add on these findings, and provide insights on the role played by both above-and below-ground plant traits and their development, as well on the whole flow regime including low flows and floods with different magnitude, duration, and frequency, which are often not considered.…”

Section: Discussionmentioning

confidence: 92%

“…Despite modelling efforts to include a more detailed description of vegetation-related feedbacks are mounting 32 , 33 , there is still a lack of appropriate models that links environmental factors with plant morphological traits and describes the associated feedbacks. So far, models have mostly treated vegetation as a whole 34 , not distinguishing between above- and below-ground traits, or have focused on spatial and temporal scales that hindered a clear identification of their role 35 , 36 .…”

Section: Introductionmentioning

confidence: 99%

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A model study of the combined effect of above and below ground plant traits on the ecomorphodynamics of gravel bars

Caponi

Vetsch

Siviglia

2020

Sci Rep

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Both above- and below-ground plant traits are known to modulate feedbacks between vegetation and river morphodynamic processes. However, how they collectively influence vegetation establishment on gravel bars remains less clear. Here we develop a numerical model that couples above- and below-ground vegetation dynamics with hydromorphological processes. The model dynamically links plant growth rate to water table fluctuations and includes plant mortality by uprooting and burial. We considered a realistic hydrological regime and used the model to simulate the coevolution of alternate gravel bars and vegetation that displays trade-offs in investment of above- and below-ground biomass. We found that a balanced plant growth above- and below-ground facilitates vegetation to establish on steady, stable bars, because it allows plants to develop traits that maximise growth performance during low flow periods and thus survival during floods. Regardless of the growth strategy, vegetation could not establish on migrating bars because of large plant loss by uprooting during floods. These findings add on previous studies suggesting that morphodynamic processes play a key role on determining plant trait distributions and highlight the importance of including the dynamics of both above- and below-ground plant traits for predicting shifts between bare and vegetated states in river bars.

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Section: Discussionmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 99%

A model study of the combined effect of above and below ground plant traits on the ecomorphodynamics of gravel bars

Caponi

Vetsch

Siviglia

2020

Sci Rep

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“…This suggests that, in our study area, sediment deposition may not be confined within the separation zone (Best, 1987) and that the enhancement of bar dimensions can be related to the presence of vegetation, which definitely plays an important role in making the bars stable (Calvani, Francalanci, & Solari, 2018;Jourdain, Claude, Tassi, Cordier, & Antoine, 2020), by promoting deposition and thus enhancing their dimensions.…”

Section: River Confluences Morphodynamics In Presence Of Riparian Vegetationmentioning

confidence: 81%

Effects of vegetation at a bar confluence on river hydrodynamics: The case study of the Arno River at Greve junction

Artini

Calvani

Francalanci

et al. 2021

River Research & Apps

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River bars often form at river confluences due to variation in flow discharges or in sediment transport capacity; once these bars are grown, they constitute favourable habitats for vegetation development. In this work, we analysed the effect of vegetation above confluence bars on the hydrodynamics of a river reach. The case study considered is the Arno River reach at the Greve junction, where confluence bars expanded towards the opposite bank. A two-dimensional hydraulic model was implemented through BASEMENT software varying the flow discharge. Three-dimensional topographic data were used to generate the calculation mesh. Dendrometric surveys were carried out to describe the current state of the vegetation. Seven different vegetative scenarios were considered for numerical simulations, depending on different vegetation management conditions. Such scenarios are characterised by various plant densities, diameters, heights and species (herbaceous, shrub and arboreal), and, accordingly, different formu-

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“…Since the end of the 20th century, there has been a relative shortage of coarse particle input, and an excess of fine particles. The resulting imbalance led to erosion of the main channel, aggradation and fixation of gravel bars due to massive fine sediment deposits and riparian vegetation growth (Jourdain et al, 2020).…”

Section: Objectives and Site Descriptionmentioning

confidence: 99%

Long term high frequency sediment observatory in an alpine catchment: The Arc‐Isère rivers, France

Thollet

Rousseau

Camenen

et al. 2021

Hydrological Processes

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We present a dataset on to the Arc-Isère long-term environmental research observatory, which is part of the Rhône Basin Long Term Environmental Research Observatory. This alpine catchment located in the French Alps is characterized by high Suspended Particulate Matter (SPM) in anthropogenized valleys. Suspended Sediment Concentrations (SSC) naturally observed in the river are very high, ranging from a few tens of milligrams per litre at low flow to tens of grams per litre during major natural hydrological events (floods, debris flows) or river dam hydraulic flushes. One research objective related to this site is to better understanding the SSC dynamics along the river using a system of nested catchments (Arvan, Arc, and Isère) in order to assess both temporal and spatial dynamics. The data allow the quantification of fine sediment yields and also the evaluation of possible morphological changes due to fine sediment deposition or resuspension. Additionally, the observatory database support studies on contaminants (either dissolved or particulate contaminants). Our monitoring includes six stations with high frequency (2-30 min) streamflow, SSC measurement using turbidity sensors, and associated automatic sampling. Discharge is measured via water level measurements and a rating curve. The oldest station (Grenoble-campus) started recording discharge and concentration data from April 2006 while others stations were built between 2009 and 2011. Data are available in an online data website called 'Base de Données des Observatoires en Hydrologie' (Hydrological observatory database, https://bdoh.irstea.fr/ARC-ISERE/) with a DOI reference for the dataset. The hydrological and sediment transport time series are stored, managed and made available to a wide community with unfettered access in order to be used at their full extent. This database is used as a data exchange tool for both scientists and operational end-users and there is an associated online tool to compute integrated fluxes.

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Morphodynamics of alternate bars in the presence of riparian vegetation

Cited by 35 publications

References 104 publications

A model study of the combined effect of above and below ground plant traits on the ecomorphodynamics of gravel bars

A model study of the combined effect of above and below ground plant traits on the ecomorphodynamics of gravel bars

Effects of vegetation at a bar confluence on river hydrodynamics: The case study of the Arno River at Greve junction

Long term high frequency sediment observatory in an alpine catchment: The Arc‐Isère rivers, France

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