Comparing the Cohesive Effects of Mud and Vegetation on Delta Evolution

Lauzon, R.; Murray, A. Brad

doi:10.1029/2018gl079405

Cited by 24 publications

(42 citation statements)

References 55 publications

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“…In addition, the modeling conducted in this study does not account for the effects of vegetation, permafrost, or ice on deltaic evolution. We note that the DeltaRCM model has been modified to simulate these effects (Lauzon & Murray, 2018; Lauzon et al., 2019; Piliouras et al., 2021), however, these modifications were kept out of this study for the sake of simplicity.…”

Section: Resultsmentioning

confidence: 99%

“…Simplified models have been developed to understand, for example, the lobate growth of delta landforms (Moodie et al., 2019; Seybold et al., 2007). Established models have been modified to explore the influence that multiple variables such as waves and SLR (Ratliff et al., 2018), mud and vegetation (Lauzon & Murray, 2018), and ice and permafrost (Lauzon et al., 2019) have on delta morphology and dynamics. In contrast to physical experiments, numerical models allow more experiments to be conducted and therefore additional conditions and forcings to be tested.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Linking the Surface and Subsurface in River Deltas—Part 1: Relating Surface and Subsurface Geometries

Hariharan

Michael

et al. 2021

Water Resources Research

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River deltas are densely populated regions of the world with vulnerable groundwater reserves. Contamination of these groundwater aquifers via saline water intrusion and pollutant transport is a growing threat due to both anthropogenic and climate changes. The arrangement and composition of subsurface sediment is known to have a significant impact on aquifer contamination; however, developing accurate depictions of the subsurface is challenging. In this work, we explore the relationship between surface and subsurface properties and identify the metrics most sensitive to different forcing conditions. To do so, we simulate river delta evolution with the rule‐based numerical model, DeltaRCM, and test the influence of input sand fraction and steady sea level rise (SLR) on delta evolution. From the model outputs, we measure a variety of surface and subsurface metrics chosen based on their applicability to imagery and modeling results. The Kullback‐Leibler (KL) divergence is then used to quantitatively gauge which metrics are most indicative of the imposed forcings. Both qualitative observations and the KL divergence analysis suggest that estimates of subsurface connectivity can be constrained using surface information. In particular, more variable shoreline roughness values and higher surface wetted fraction values correspond to increased subsurface connectivity. These findings complement traditional methods of estimating subsurface structure in river‐dominated delta systems and represent a step toward the identification of a direct link between surface observations and subsurface form.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Linking the Surface and Subsurface in River Deltas—Part 1: Relating Surface and Subsurface Geometries

Hariharan

Michael

et al. 2021

Water Resources Research

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show abstract

“…For example, Toby et al () recognized that the scale of autogenic volume fluctuations that defines transfer thresholds likely varies as a function of the mean and stochastic components of a system's forcing. Work to define the magnitude of autogenic fluctuations as functions of forcing conditions is starting to accelerate, with studies quantifying autogenic scales as functions of the ratio of sediment to water supply (Powell et al, ; Straub & Wang, ), sediment grain size (Caldwell & Edmonds, ) and cohesion (Edmonds & Slingerland, ; Hoyal & Sheets, ; Li et al, ), vegetation (Lauzon & Murray, ; Piliouras et al, ), flashiness of system hydrographs (Esposito et al, ; Ganti et al, ; Miller et al, ), basin water depth (Carlson et al, ), and wave (Ratliff et al, ) and tidal climate (Kleinhans et al, ; Lentsch et al, ).…”

Section: Future Directionsmentioning

confidence: 99%

Buffered, Incomplete, and Shredded: The Challenges of Reading an Imperfect Stratigraphic Record

et al. 2020

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Climate, tectonics, and life influence the flux and caliber of sediment transported across Earth's surface. These environmental conditions can leave behind imprints in the Earth's sedimentary archive, but signals of climate, tectonic, and biologic change are not always present in the stratigraphic record. Deterministic and stochastic surface dynamics collectively act as a stratigraphic filter, impeding the burial and preservation of environmental signals in sedimentary deposits. Such impediments form a central challenge to accurately reconstructing environmental conditions through Earth's history. Emergent and self‐organized length and timescales in landscapes, which are themselves influenced by regional environmental conditions, define spatial and temporal sedimentation patterns in basins and fundamentally control the likelihood of environmental signal preservation in sedimentary deposits. Properly characterizing these scales provides a key avenue for incorporating the known “imperfections” of the stratigraphic record into paleoenvironmental reconstructions. These insights are necessary for answering both basic and applied science questions, including our ability to reconstruct the Earth system response to prior episodes of climate, tectonic, or land cover change.

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“…Simulations used the DeltaRCM numerical delta model , implemented in Python as pyDeltaRCM (Moodie, Hariharan, Barefoot, & Passalacqua, in review). DeltaRCM has been robustly validated (Liang, Ge-leynse, Edmonds, & Passalacqua, 2015b; and used to examine delta morphology and evolution under various external forcings, including sea-level rise , and presence of vegetation (Lauzon & Murray, 2018), and ice and permafrost (Lauzon, Piliouras, & Rowland, 2019;Piliouras, Lauzon, & Rowland, 2021). The perturbation was modeled as instantaneous vertical land movement (i.e., displacement without hanging-wall rotation or translation), with channel evolution and geometry before and following displacement emerging based on model boundary conditions (Supporting Information).…”

Section: Simulating Faulting-induced Subsidence Across a Range Of Scalesmentioning

confidence: 99%

When does faulting-induced subsidence drive distributary network reorganization?

Moodie¹,

Passalacqua²

2022

Preprint

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Deltas exhibit spatially and temporally variable subsidence, including vertical displacement due to movement along fault planes. Faulting-induced subsidence perturbs delta-surface gradients, potentially causing distributary networks to shift sediment dispersal within the landscape. Sediment dispersal restricted to part of the landscape could hinder billion-dollar investments aiming to restore delta land, making faulting-induced subsidence a significant, yet unconstrained hazard to these projects. In this study, we modeled a range of displacement events in disparate deltaic environments, and observe that a channelized connection with the displaced area determines whether a distributary network reorganizes. When this connection exists, the magnitude of distributary network reorganization is predicted by a ratio relating dimensions of faulting-induced subsidence and channel geometry. We use this ratio to extend results to real-world deltas and assess hazards to deltaic-land building projects.

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Comparing the Cohesive Effects of Mud and Vegetation on Delta Evolution

Cited by 24 publications

References 55 publications

Linking the Surface and Subsurface in River Deltas—Part 1: Relating Surface and Subsurface Geometries

Linking the Surface and Subsurface in River Deltas—Part 1: Relating Surface and Subsurface Geometries

Buffered, Incomplete, and Shredded: The Challenges of Reading an Imperfect Stratigraphic Record

When does faulting-induced subsidence drive distributary network reorganization?

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