Complexities in barrier island response to sea level rise: Insights from numerical model experiments, North Carolina Outer Banks

Moore, Laura J.; List, Jeffrey H.; Williams, S. Jeffress; Stolper, David

doi:10.1029/2009jf001299

Cited by 120 publications

(138 citation statements)

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“…In that case, the assumption of an encroachment response is no longer valid, and the model will likely over-estimate potential shoreline recession. When considering the well-developed dune morphology of most NSW beaches, relative to low-relief barrier island coasts e.g., [64], and following manual review of the regional-scale model predictions, we are confident that this limitation does not affect the model scenarios that are considered in our exposure assessment (i.e., present-1% exceedance, 2050-1% exceedance, and 2100-50% exceedance forecasts). In some settings, however, low-exceedance (e.g., 1%) and long-term (e.g., 2100) forecasts may over-estimate potential shoreline change ( Figure 11A).…”

Section: Modelling Approach and Limitationsmentioning

confidence: 99%

“…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: Modelling Approach and Limitationsmentioning

confidence: 99%

Section: Simple Shoreline Encroachment Modelmentioning

confidence: 99%

Section: Modelling Approach and Limitationsmentioning

confidence: 99%

See 1 more Smart Citation

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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“…This well-documented history when conjoined with the results of numerical modeling experiments implies that barrier islands can migrate landward (high resiliency), disintegrate over time (low resiliency), or drown in place (lowest resiliency) as sea level rises and sand supplies diminish (LorenzoTrueba and Ashton 2013; Moore et al 2009). It seems clear that the former outcome should be favored by conservation policies and not the latter two Bterminal^states.…”

Section: What Do We Mean By the Natural Resiliency Of Barrier Islands?mentioning

confidence: 95%

“…However, we do understand their general evolutionary trajectory. For example, geologic histories of barrier islands and computer modeling results (Lorenzo-Trueba and Ashton 2013; Moore et al 2009;Masetti et al 2008) indicate that many barrier islands over the forthcoming centuries and millennia will respond to rising sea level by migrating landward. If resilience thinking were deeply understood, one would hope that most inhabitants of barrier islands would opt to adapt to rather than oppose this dynamic process.…”

Section: How Can Resilience Thinking Translate Into Management Policy?mentioning

confidence: 97%

A millennium-long management perspective for promoting the geological-social resiliency of barrier islands: a preliminary proposal for Fire Island, NY

Pinet

2015

J Environ Stud Sci

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Barrier islands, such as Fire Island, NY, are complex geological-social systems, driven by mesoscale (centuries/ millennia) processes. The natural resiliency of these thin, linear landforms depends mainly on their capacity to migrate landward (rollover) in response to the slow, persistent rise of sea level. This happens by overwash processes during storm surges, whereby beach and dune sand on the ocean side is eroded and transferred to the island's interior and back-barrier shore. Also storm breaches and inlet formation enable the development of flood-tidal deltas, which likewise supply large volumes of sand to the backshore of barriers. If these processes are curtailed by shortsighted engineering solutions, barrier islands will lose their morphologic resiliency and either disintegrate or drown in place. The ideas in this paper argue for a millennial management perspective for Fire Island, based on not interfering with the process of rollover over geologically significant spans of time. To be effective, people will need to think about adapting to continual change on a system level, rather than relying on conventional, short-term engineering solutions to a local erosion problem, a management strategy that will compromise the morphologic integrity of Fire Island as sea level continues to rise for the foreseeable future.

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

2014

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We construct a simple morphodynamic model to investigate the long-term dynamic evolution of a coastal barrier system experiencing sea-level rise. Using a simplified barrier geometry, the model includes a dynamic shoreface profile that can be out of equilibrium and explicitly treats barrier sediment overwash as a flux. With barrier behavior primarily controlled by the maximum potential overwash flux and the rate of shoreface response, the modeled barrier system demonstrates four primary behaviors: height drowning, width drowning, constant landward retreat, and a periodic retreat. Height drowning occurs when overwash fluxes are insufficient to maintain the landward migration rate required to keep pace with sea-level rise. On the other hand, width drowning occurs when the shoreface response rate is insufficient to maintain the barrier geometry during overwash-driven landward migration. During periodic barrier retreat, the barrier experiences oscillating periods of rapid overwash followed by periods of relative stability as the shoreface resteepens. This periodic retreat, which occurs even with a constant sea-level rise rate, arises when overwash rates and shoreface response rates are large and of similar magnitude. We explore the occurrence of these behaviors across a wide range of parameter values and find that in addition to the maximum overwash flux and the shoreface response rate, barrier response can be particularly sensitive to the sea-level rise rate and back-barrier lagoon slope. Overall, our findings contrast with previous research which has primarily associated complex barrier behavior with changes in external forcing such as sea-level rise rate, sediment supply, or back-barrier geometry.

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Complexities in barrier island response to sea level rise: Insights from numerical model experiments, North Carolina Outer Banks

Cited by 120 publications

References 58 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

A millennium-long management perspective for promoting the geological-social resiliency of barrier islands: a preliminary proposal for Fire Island, NY

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

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