Channel mobility drives a diverse stratigraphic architecture in the dryland Mojave River (California, USA)

Ielpi, Alessandro; Lapôtre, M. G. A.; Finotello, Alvise; Ghinassi, Massimiliano; D’Alpaos, Andrea

doi:10.1002/esp.4841

Cited by 17 publications

(26 citation statements)

References 96 publications

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“…With a pattern similar to other desert‐climate rivers in the Great Basin and beyond (e.g. Singer and Michaelides, 2014; Michaelides et al ., 2018; Ielpi et al ., 2020), our field estimates indicate that bankfull discharge, Q b (Table 1), is lowest upstream (Elko), reaches a maximum in the mid‐upper reaches (Beowave), and then decreases downstream, although irregularly, with a secondary high at Emigrant Canyon. Collectively, our estimates define a median ± 1σ Q b of

{96.80}_{- 24.96}^{+ 84.28}

m 3 s −1 .…”

Section: Resultsmentioning

confidence: 65%

“…To evaluate potential hydraulic controls on meander‐cutoff incidence (Lane, 1947; Schwenk and Foufoula‐Georgiou, 2016), we use a proxy for the backwater length scale, L b = h / S , as an indication of the distance over which non‐uniform flow conditions may occur upstream of an initial cutoff (Chow, 1959). To estimate the values of h needed to extrapolate the backwater length scale where we do not have ground measurements, we employ a best‐fit power law derived from Great Basin rivers: h = 0.05 w 1.07 ( R 2 = 0.76; from Ielpi et al ., 2020); local values of S along individual meander bends are approximated as S avg / χ ; whereas this approximation relies on comparatively coarse SRTM data, the large number of meanders in our dataset prevents biases from potentially spurious estimates. A nondimensional backwater length scale is then defined as

L_{b}^{*} = L_{b} / L_{avg}

, where L avg is the average of all meander lengths in our dataset (including both cutoff and non‐cutoff), and thus expresses the backwater length in units of meander lengths.…”

Section: Datasets and Methodsmentioning

confidence: 99%

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Planform‐asymmetry and backwater effects on river‐cutoff kinematics and clustering

Ielpi

Lapôtre

Finotello

et al. 2020

Earth Surf Processes Landf

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River bends occasionally meander to the point of cutoff, whereby a river shortcuts itself and isolates a portion of its course. This fundamental process fingerprints a river's long‐term planform geometry, its stratigraphic record, and biogeochemical fluxes in the floodplain. Although meander cutoffs are common in fast‐migrating channels, timelapse imagery of the Earth surface typically does not offer a long enough baseline for statistically robust analyses of these processes. We seek to bridge this gap by quantifying cutoff kinematics along the Humboldt River (Nevada) – a stream that, from 1994 to 2019, hosted an exceptionally high number of cutoffs (specifically, 174 of the chute type and 53 of the neck type). A coincidence between major floods and cutoff incidence is first suggestive of hydrographic modulation. Moreover, not just higher sinuosity but also upstream planform skewness is associated with higher cutoff incidence and channel widening for a sub‐population of chute cutoffs. We propose a conceptual model to explain our results in terms of channel‐flow structure and then examine the distances between adjacent cutoffs to understand the mechanisms governing their clustering. We find that both local and nonlocal perturbations together trigger the clustering of new cutoffs, over distances capped by the backwater length and over yearly to decadal timescales. Our research suggests that planform geometry and backwater controls might sway the occurrence of cutoff clusters – both local and nonlocal – thereby offering new testable hypotheses to explore the evolution of meandering‐river landscapes that have significant implications for river engineering and stratigraphic modelling. © 2020 John Wiley & Sons, Ltd.

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{96.80}_{- 24.96}^{+ 84.28}

m 3 s −1 .…”

Section: Resultsmentioning

confidence: 65%

L_{b}^{*} = L_{b} / L_{avg}

, where L avg is the average of all meander lengths in our dataset (including both cutoff and non‐cutoff), and thus expresses the backwater length in units of meander lengths.…”

Section: Datasets and Methodsmentioning

confidence: 99%

Planform‐asymmetry and backwater effects on river‐cutoff kinematics and clustering

Ielpi

Lapôtre

Finotello

et al. 2020

Earth Surf Processes Landf

Self Cite

View full text Add to dashboard Cite

show abstract

“…With the help of SRTM and in-situ information they were able to demonstrate that the loss of river meander was caused by a relative elevation of the land surface or a lowering of the sea level. Lelpi et al [232] used SRTM RS data to investigate the relationships between the incidence of floods and the speed of change to the channel migration rate in arid regions. They achieved this by combining the data from discharge records with channel migration rates, dynamic time-warping analysis, and chronologically calibrated subsidence rates derived from RS data.…”

Section: Fluvial and Tidal Channel Migrationmentioning

confidence: 99%

Linking the Remote Sensing of Geodiversity and Traits Relevant to Biodiversity—Part II: Geomorphology, Terrain and Surfaces

Lausch

Schaepman

Skidmore³

et al. 2020

Remote Sensing

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The status, changes, and disturbances in geomorphological regimes can be regarded as controlling and regulating factors for biodiversity. Therefore, monitoring geomorphology at local, regional, and global scales is not only necessary to conserve geodiversity, but also to preserve biodiversity, as well as to improve biodiversity conservation and ecosystem management. Numerous remote sensing (RS) approaches and platforms have been used in the past to enable a cost-effective, increasingly freely available, comprehensive, repetitive, standardized, and objective monitoring of geomorphological characteristics and their traits. This contribution provides a state-of-the-art review for the RS-based monitoring of these characteristics and traits, by presenting examples of aeolian, fluvial, and coastal landforms. Different examples for monitoring geomorphology as a crucial discipline of geodiversity using RS are provided, discussing the implementation of RS technologies such as LiDAR, RADAR, as well as multi-spectral and hyperspectral sensor technologies. Furthermore, data products and RS technologies that could be used in the future for monitoring geomorphology are introduced. The use of spectral traits (ST) and spectral trait variation (STV) approaches with RS enable the status, changes, and disturbances of geomorphic diversity to be monitored. We focus on the requirements for future geomorphology monitoring specifically aimed at overcoming some key limitations of ecological modeling, namely: the implementation and linking of in-situ, close-range, air- and spaceborne RS technologies, geomorphic traits, and data science approaches as crucial components for a better understanding of the geomorphic impacts on complex ecosystems. This paper aims to impart multidimensional geomorphic information obtained by RS for improved utilization in biodiversity monitoring.

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“…Like other fluvial bars, stratal architecture and distribution of sedimentary facies in point bars are generally constructed when discharge reaches or exceeds bankfull conditions, whereas lower discharges reshape these deposits (Moody & Meade, 2014; Blom et al ., 2017; Naito & Parker, 2019; Francalanci et al ., 2020; Ielpi et al ., 2020). Although the importance of bankfull discharge in constructing bars is largely acknowledged, linking hydrology of river floods with related deposits has been the goal of a limited number of studies (Fielding et al ., 1999; Sambrook Smith et al ., 2010) and changes in sedimentary processes during floods is still poorly known.…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of an extreme flood hydrograph and morphodynamics of a meander bend in a high‐peak discharge variability river (Powder River, USA)

Ghinassi

Moody

2021

Sedimentology

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Understanding of morphodynamic processes associated with large-scale floods has recently improved following significant advances of modern technologies. Nevertheless, a clear link between flood discharge and in-channel sedimentation processes remains to be resolved. The hydrological and geomorphological data available for the meandering Powder River (Montana, USA) since 1977 makes it a perfect laboratory to investigate connections between flood discharge and point-bar sedimentation processes. This study focuses on a pointbar that accreted laterally ca 70 m during a 50-year recurrence flood, which lasted about 14 days in May 1978. In September 2018, a trench ca 2 m deep and 70 m long was excavated through the axial point-bar deposits, and the 1978 flood deposits were delineated based on georeferenced pre-flood and post-flood cross-section surveys. Sedimentological data show that point-bar deposits accumulated at the early and late flood stages, when the flow was confined to the channel, and have similarities with classical facies models in terms of palaeocurrent patterns and vertical grain-size trend. However, during high-stage flood conditions, when the flow overtopped the bar, cross-cutting of the bar and armouring were typical processes. Integration of sedimentological and palaeo-hydrological data highlight that the relation between channel cross-sectional area and flood discharge play a key role in preserving bar deposits. The integrated approach adopted here provides a basis for advancing palaeoflood hydrology beyond the stage of estimating peak discharges to the next stage of estimating palaeoflood hydrographs.

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Channel mobility drives a diverse stratigraphic architecture in the dryland Mojave River (California, USA)

Cited by 17 publications

References 96 publications

Planform‐asymmetry and backwater effects on river‐cutoff kinematics and clustering

Planform‐asymmetry and backwater effects on river‐cutoff kinematics and clustering

Linking the Remote Sensing of Geodiversity and Traits Relevant to Biodiversity—Part II: Geomorphology, Terrain and Surfaces

Reconstruction of an extreme flood hydrograph and morphodynamics of a meander bend in a high‐peak discharge variability river (Powder River, USA)

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