Hurricane Sandy Effects on Coastal Marsh Elevation Change

Alice G. Yeates; James B. Grace; Jennifer H. Olker; Glenn R. Guntenspergen; Donald R. Cahoon; Susan Adamowicz; Shimon C. Anisfeld; Nels Barrett; Alice Benzecry; Linda Blum; Robert R. Christian; Joseph Grzyb; Ellen Kracauer Hartig; Kelly Hines Leo; Scott Lerberg; James C. Lynch; Nicole Maher; J. Patrick Megonigal; William Reay; Drexel Siok; Adam Starke; Vincent Turner; Scott Warren

doi:10.1007/s12237-020-00758-5

Hurricane Sandy Effects on Coastal Marsh Elevation Change

Alice G. Yeates, James B. Grace, Jennifer H. Olker, Glenn R. Guntenspergen, Donald R. Cahoon, Susan Adamowicz, Shimon C. Anisfeld, Nels Barrett, Alice Benzecry, Linda Blum, Robert R. Christian, Joseph Grzyb, Ellen Kracauer Hartig, Kelly Hines Leo, Scott Lerberg, James C. Lynch, Nicole Maher, J. Patrick Megonigal, William Reay, Drexel SiokAdam Starke, Vincent Turner, Scott Warren

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

High-magnitude storm events such as Hurricane Sandy are powerful agents of geomorphic change in coastal marshes, potentially altering their surface elevation trajectories. But how do a storm’s impacts vary across a large region spanning a variety of wetland settings and storm exposures and intensities. We determined the short-term impacts of Hurricane Sandy at 223 surface elevation table–marker horizon stations in estuarine marshes located across the northeast region of the United States by comparing post-storm surface elevation change with pre-storm elevation trends. We hypothesized that the storm’s effect on marsh elevation trends would be influenced by position relative to landfall (right or left) and distance from landfall. The structural equation model presented predicts that marshes located to the left of landfall were more likely to experience an elevation gain greater than expected, and this positive deviation from pre-storm elevation trends tended to have a greater magnitude than those experiencing negative deviations (elevation loss), potentially due to greater sediment deposition. The magnitude of negative deviations from elevation change in marshes to the right of landfall was greater than for positive deviations, with a greater effect in marshes within 200 km of landfall, potentially from the extent and magnitude of storm surge. Overall, results provide an integrated picture of how storm characteristics combined with the local wetland setting are important to a storm’s impact on surface elevation, and that the surface elevation response can vary widely among sites across a region impacted by the same storm.

Original language	English (US)
Pages (from-to)	1640-1657
Number of pages	18
Journal	Estuaries and Coasts
Volume	43
Issue number	7
DOIs	https://doi.org/10.1007/s12237-020-00758-5
State	Published - Nov 1 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020, This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply.

Keywords

Hurricane Sandy
Marsh dynamics
SET-MH
Storm impacts
Structural equation modeling
Surface elevation table
marker horizon

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10.1007/s12237-020-00758-5

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Yeates, A. G., Grace, J. B., Olker, J. H., Guntenspergen, G. R., Cahoon, D. R., Adamowicz, S., Anisfeld, S. C., Barrett, N., Benzecry, A., Blum, L., Christian, R. R., Grzyb, J., Hartig, E. K., Leo, K. H., Lerberg, S., Lynch, J. C., Maher, N., Megonigal, J. P., Reay, W., ... Warren, S. (2020). Hurricane Sandy Effects on Coastal Marsh Elevation Change. Estuaries and Coasts, 43(7), 1640-1657. https://doi.org/10.1007/s12237-020-00758-5

Yeates, AG, Grace, JB, Olker, JH, Guntenspergen, GR, Cahoon, DR, Adamowicz, S, Anisfeld, SC, Barrett, N, Benzecry, A, Blum, L, Christian, RR, Grzyb, J, Hartig, EK, Leo, KH, Lerberg, S, Lynch, JC, Maher, N, Megonigal, JP, Reay, W, Siok, D, Starke, A, Turner, V & Warren, S 2020, 'Hurricane Sandy Effects on Coastal Marsh Elevation Change', Estuaries and Coasts, vol. 43, no. 7, pp. 1640-1657. https://doi.org/10.1007/s12237-020-00758-5

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abstract = "High-magnitude storm events such as Hurricane Sandy are powerful agents of geomorphic change in coastal marshes, potentially altering their surface elevation trajectories. But how do a storm{\textquoteright}s impacts vary across a large region spanning a variety of wetland settings and storm exposures and intensities. We determined the short-term impacts of Hurricane Sandy at 223 surface elevation table–marker horizon stations in estuarine marshes located across the northeast region of the United States by comparing post-storm surface elevation change with pre-storm elevation trends. We hypothesized that the storm{\textquoteright}s effect on marsh elevation trends would be influenced by position relative to landfall (right or left) and distance from landfall. The structural equation model presented predicts that marshes located to the left of landfall were more likely to experience an elevation gain greater than expected, and this positive deviation from pre-storm elevation trends tended to have a greater magnitude than those experiencing negative deviations (elevation loss), potentially due to greater sediment deposition. The magnitude of negative deviations from elevation change in marshes to the right of landfall was greater than for positive deviations, with a greater effect in marshes within 200 km of landfall, potentially from the extent and magnitude of storm surge. Overall, results provide an integrated picture of how storm characteristics combined with the local wetland setting are important to a storm{\textquoteright}s impact on surface elevation, and that the surface elevation response can vary widely among sites across a region impacted by the same storm.",

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AU - Guntenspergen, Glenn R.

AU - Cahoon, Donald R.

AU - Adamowicz, Susan

AU - Anisfeld, Shimon C.

AU - Barrett, Nels

AU - Benzecry, Alice

AU - Blum, Linda

AU - Christian, Robert R.

AU - Grzyb, Joseph

AU - Hartig, Ellen Kracauer

AU - Leo, Kelly Hines

AU - Lerberg, Scott

AU - Lynch, James C.

AU - Maher, Nicole

AU - Megonigal, J. Patrick

AU - Reay, William

AU - Siok, Drexel

AU - Starke, Adam

AU - Turner, Vincent

AU - Warren, Scott

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N2 - High-magnitude storm events such as Hurricane Sandy are powerful agents of geomorphic change in coastal marshes, potentially altering their surface elevation trajectories. But how do a storm’s impacts vary across a large region spanning a variety of wetland settings and storm exposures and intensities. We determined the short-term impacts of Hurricane Sandy at 223 surface elevation table–marker horizon stations in estuarine marshes located across the northeast region of the United States by comparing post-storm surface elevation change with pre-storm elevation trends. We hypothesized that the storm’s effect on marsh elevation trends would be influenced by position relative to landfall (right or left) and distance from landfall. The structural equation model presented predicts that marshes located to the left of landfall were more likely to experience an elevation gain greater than expected, and this positive deviation from pre-storm elevation trends tended to have a greater magnitude than those experiencing negative deviations (elevation loss), potentially due to greater sediment deposition. The magnitude of negative deviations from elevation change in marshes to the right of landfall was greater than for positive deviations, with a greater effect in marshes within 200 km of landfall, potentially from the extent and magnitude of storm surge. Overall, results provide an integrated picture of how storm characteristics combined with the local wetland setting are important to a storm’s impact on surface elevation, and that the surface elevation response can vary widely among sites across a region impacted by the same storm.

AB - High-magnitude storm events such as Hurricane Sandy are powerful agents of geomorphic change in coastal marshes, potentially altering their surface elevation trajectories. But how do a storm’s impacts vary across a large region spanning a variety of wetland settings and storm exposures and intensities. We determined the short-term impacts of Hurricane Sandy at 223 surface elevation table–marker horizon stations in estuarine marshes located across the northeast region of the United States by comparing post-storm surface elevation change with pre-storm elevation trends. We hypothesized that the storm’s effect on marsh elevation trends would be influenced by position relative to landfall (right or left) and distance from landfall. The structural equation model presented predicts that marshes located to the left of landfall were more likely to experience an elevation gain greater than expected, and this positive deviation from pre-storm elevation trends tended to have a greater magnitude than those experiencing negative deviations (elevation loss), potentially due to greater sediment deposition. The magnitude of negative deviations from elevation change in marshes to the right of landfall was greater than for positive deviations, with a greater effect in marshes within 200 km of landfall, potentially from the extent and magnitude of storm surge. Overall, results provide an integrated picture of how storm characteristics combined with the local wetland setting are important to a storm’s impact on surface elevation, and that the surface elevation response can vary widely among sites across a region impacted by the same storm.

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KW - Structural equation modeling

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Hurricane Sandy Effects on Coastal Marsh Elevation Change

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