Rollover, drowning, and discontinuous retreat: Distinct modes of barrier response to sea‐level rise arising from a simple morphodynamic model

Lorenzo‐Trueba, Jorge; Ashton, Andrew D.

doi:10.1002/2013jf002941

Cited by 178 publications

(237 citation statements)

References 78 publications

(133 reference statements)

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“…Our model does not support continuous (rollover) or discontinuous (drowning, overstepping) dynamic barrier behaviours [64,65], and is therefore only applicable to simulating shoreline recession on relatively steep, moderate to high energy wave-dominated coasts, where the existing beach and dune morphology is well-developed. The model is not suitable for simulating shoreline change on low-lying barrier island coasts, where dynamic barrier behaviour controls shoreline change [64][65][66].…”

Section: Simple Shoreline Encroachment Modelmentioning

confidence: 99%

“…While the washover parameter (V O ) could be used to simulate the effect of washover deposition or dune growth in slowing the rate of shoreline recession, we neglect its use due to lack of data or previous examples. Nonetheless, a more rigorous dynamic barrier model [64,65,78] could be implemented within the framework to address these processes in more detail. We emphasise again that the model as applied here is intended to provide a risk-averse mid-resolution forecast of potential shoreline change.…”

Section: Modelling Approach and Limitationsmentioning

confidence: 99%

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Second-Pass Assessment of Potential Exposure to Shoreline Change in New South Wales, Australia, Using a Sediment Compartments Framework

Kinsela

Morris

Linklater

et al. 2017

JMSE

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Abstract:The impacts of coastal erosion are expected to increase through the present century, and beyond, as accelerating global mean sea-level rise begins to enhance or dominate local shoreline dynamics. In many cases, beach (and shoreline) response to sea-level rise will not be limited to passive inundation, but may be amplified or moderated by sediment redistribution between the beach and the broader coastal sedimentary system. We describe a simple and scalable approach for estimating the potential for beach erosion and shoreline change on wave-dominated sandy beaches, using a coastal sediment compartments framework to parameterise the geomorphology and connectivity of sediment-sharing coastal systems. We apply the approach at regional and local scales in order to demonstrate the sensitivity of forecasts to the available data. The regional-scale application estimates potential present and future asset exposure to coastal erosion in New South Wales, Australia. The assessment suggests that shoreline recession due to sea-level rise could drive a steep increase in the number and distribution of asset exposure in the present century. The local-scale example demonstrates the potential sensitivity of erosion impacts to the distinctive coastal geomorphology of individual compartments. Our findings highlight that the benefits of applying a coastal sediment compartments framework increase with the coverage and detail of geomorphic data that is available to parameterise sediment-sharing systems and sediment budget principles. Such data is crucial to reducing uncertainty in forecasts by understanding the potential response of key sediment sources and sinks (e.g., the shoreface, estuaries) to sea-level rise in different settings.

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Section: Simple Shoreline Encroachment Modelmentioning

confidence: 99%

Section: Modelling Approach and Limitationsmentioning

confidence: 99%

Second-Pass Assessment of Potential Exposure to Shoreline Change in New South Wales, Australia, Using a Sediment Compartments Framework

Kinsela

Morris

Linklater

et al. 2017

JMSE

View full text Add to dashboard Cite

show abstract

“…The fate of modern barrier islands on coasts with rapid and accelerating sea level rise depends greatly on the retreat rate barrier islands can achieve. Many models of barrier island response to sea level rise consider landward retreat to depend on overwash fluxes: storm-induced episodic sediment supplied from the nearshore environment that overtops barriers and is deposited on backbarrier marshes [Stolper et al, 2005;Lorenzo-Trueba and Ashton, 2014]. Given that 50% of barrier complexes show tidal inlet fill sequences [Moslow and Tye, 1985], inlet migration, through flood-tidal delta deposition, is likely also an important sediment mover that allows barrier islands to transgress.…”

Section: Implications For Barrier Island Evolutionmentioning

confidence: 99%

Mechanics and rates of tidal inlet migration: Modeling and application to natural examples

Nienhuis

Ashton

2016

JGR Earth Surface

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Tidal inlets on barrier coasts can migrate alongshore hundreds of meters per year, often presenting great management and engineering challenges. Here we perform model experiments with migrating tidal inlets in Delft3D‐SWAN to investigate the mechanics and rates of inlet migration. Model experiments with obliquely approaching waves suggest that tidal inlet migration occurs due to three mechanisms: (1) littoral sediment deposition along the updrift inlet bank, (2) wave‐driven sediment transport preferentially eroding the downdrift bank of the inlet, and (3) flood‐tide‐driven flow preferentially cutting along the downdrift inlet bank because it is less obstructed by flood‐tidal delta deposits. To quantify tidal inlet migration, we propose and apply a simple mass balance framework of sediment fluxes around inlets that includes alongshore sediment bypassing and flood‐tidal delta deposition. In model experiments, both updrift littoral sediment and the eroded downdrift inlet bank are sediment sources to the growing updrift barrier and the flood‐tidal delta, such that tidal inlets can be net sink of up to 150% of the littoral sediment flux. Our mass balance framework demonstrates how, with flood‐tidal deltas acting as a littoral sediment sink, migrating tidal inlets can drive erosion of the downdrift barrier beach. Parameterizing model experiments, we propose a predictive model of tidal inlet migration rates based upon the relative momentum flux of the inlet jet and the alongshore radiation stress; we then compare these predicted migration rates to 22 natural tidal inlets along the U.S. East Coast and find good agreement.

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“…A diversion of 25% of the current Mississippi River flux [Kim et al, 2009b] would be fluvially-dominated. However, as sea-level rise continues to threaten the existence of barrier islands [Lorenzo-Trueba and Ashton, 2014], these sites might in the future become increasingly exposed to waves. The Brazos River delta, Texas, USA, diverted in 1929, is an example where exposure to waves led to the growth of wave-sculpted shorelines [Rodriguez et al, 2000].…”

Section: Potential Littoral Transportmentioning

confidence: 99%

Plan-view evolution of wave-dominated deltas

Nienhuis¹

2016

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Ocean waves are a powerful sediment transport mechanism in the coastal zone. This thesis investigates how waves shape deltaic landforms and how small scale river mouth processes affect large-scale delta morphology. I have developed and applied models of plan-view delta shape and their channel dynamics. Simple parameterizations and key insights from these models have allowed us to transcend spatial scales from river mouths to delta plains and make morphologic predictions around the globe for every delta on Earth. I have applied models of delta morphology to backtrack the late Holocene evolution of the Ebro River delta in Spain and estimate timescales and magnitude of past climate change and human impacts. Currently, many deltas around the world face large sediment deficits because of river damming. I model deltaic response to reductions in sediment load and offer frameworks to predict future deltaic change in these dynamic and threatened coastal regions.

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Rollover, drowning, and discontinuous retreat: Distinct modes of barrier response to sea‐level rise arising from a simple morphodynamic model

Cited by 178 publications

References 78 publications

Second-Pass Assessment of Potential Exposure to Shoreline Change in New South Wales, Australia, Using a Sediment Compartments Framework

Second-Pass Assessment of Potential Exposure to Shoreline Change in New South Wales, Australia, Using a Sediment Compartments Framework

Mechanics and rates of tidal inlet migration: Modeling and application to natural examples

Plan-view evolution of wave-dominated deltas

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