Predictions of barrier island berm evolution in a time-varying storm climatology

Predictions of barrier island berm evolution in a time-varying storm climatology

Low‐lying barrier islands are ubiquitous features of the world's coastlines, and the processes responsible for their formation, maintenance, and destruction are related to the evolution of smaller, superimposed features including sand dunes, beach berms, and sandbars. The barrier island and its...

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Veröffentlicht in:Journal of geophysical research. Earth surface 2014-02, Vol.119 (2), p.300-316
Hauptverfasser: Plant, Nathaniel G., Flocks, James, Stockdon, Hilary F., Long, Joseph W., Guy, Kristy, Thompson, David M., Cormier, Jamie M., Smith, Christopher G., Miselis, Jennifer L., Dalyander, P. Soupy
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Barrier islands
Barriers
Berms
climate
Climatology
Dunes
Estimating
Evolution
Islands
Marine
Mathematical models
morphology
overwash
Sand
Sand bars
Shorelines
Storms
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container_end_page 316
container_issue 2
container_start_page 300
container_title Journal of geophysical research. Earth surface
container_volume 119
creator Plant, Nathaniel G.
Flocks, James
Stockdon, Hilary F.
Long, Joseph W.
Guy, Kristy
Thompson, David M.
Cormier, Jamie M.
Smith, Christopher G.
Miselis, Jennifer L.
Dalyander, P. Soupy
description Low‐lying barrier islands are ubiquitous features of the world's coastlines, and the processes responsible for their formation, maintenance, and destruction are related to the evolution of smaller, superimposed features including sand dunes, beach berms, and sandbars. The barrier island and its superimposed features interact with oceanographic forces (e.g., overwash) and exchange sediment with each other and other parts of the barrier island system. These interactions are modulated by changes in storminess. An opportunity to study these interactions resulted from the placement and subsequent evolution of a 2 m high sand berm constructed along the northern Chandeleur Islands, LA. We show that observed berm length evolution is well predicted by a model that was fit to the observations by estimating two parameters describing the rate of berm length change. The model evaluates the probability and duration of berm overwash to predict episodic berm erosion. A constant berm length change rate is also predicted that persists even when there is no overwash. The analysis is extended to a 16 year time series that includes both intraannual and interannual variability of overwash events. This analysis predicts that as many as 10 or as few as 1 day of overwash conditions would be expected each year. And an increase in berm elevation from 2 m to 3.5 m above mean sea level would reduce the expected frequency of overwash events from 4 to just 0.5 event‐days per year. This approach can be applied to understanding barrier island and berm evolution at other locations using past and future storm climatologies. Key Points Barrier island berm evolution is predictablePredictions depend on different storm climatologies and berm heightsResults are applicable to a broad range of natural and restored features
doi_str_mv 10.1002/2013JF002871
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source Wiley-Blackwell Journals; Wiley Free Archive; Wiley Online Library AGU Free Content
subjects Barrier islands
Barriers
Berms
climate
Climatology
Dunes
Estimating
Evolution
Islands
Marine
Mathematical models
morphology
overwash
Sand
Sand bars
Shorelines
Storms
title Predictions of barrier island berm evolution in a time-varying storm climatology
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