Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions
Foraminifera from salt-marsh environments have been used extensively in quantitative relative sea-level reconstructions due to their strong relationship with tidal level. However, the influence of temporal and spatial variability of salt-marsh foraminifera on quantitative reconstructions remains unc...
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Science::Geology Sea-Level Reconstruction Salt-Marsh Foraminifera Variability |
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Science::Geology Sea-Level Reconstruction Salt-Marsh Foraminifera Variability Walker, Jennifer S. Cahill, Niamh Khan, Nicole S. Shaw, Timothy Adam Barber, Don Miller, Kenneth G. Kopp, Robert E. Horton, Benjamin Peter Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
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Foraminifera from salt-marsh environments have been used extensively in quantitative relative sea-level reconstructions due to their strong relationship with tidal level. However, the influence of temporal and spatial variability of salt-marsh foraminifera on quantitative reconstructions remains unconstrained. Here, we conducted a monitoring study of foraminifera from four intertidal monitoring stations in New Jersey from high marsh environments over three years that included several extreme weather (temperature, precipitation, and storm surge) events. We sampled four replicates from each station seasonally (four times per year) for a total of 188 samples. The dead foraminiferal assemblages were separated into four site-specific assemblages. After accounting for systematic trends in changes in foraminifera over time among stations, the distribution of foraminiferal assemblages across monitoring stations explained ~87% of the remaining variation, while ~13% can be explained by temporal and/or spatial variability among the replicate samples. We applied a Bayesian transfer function to estimate the elevation of the four monitoring stations. All samples from each station predicted an elevation estimate within a 95% uncertainty interval consistent with the observed elevation of that station. Combining samples into replicate- and seasonal-aggregate datasets decreased elevation estimate uncertainty, with the greatest decrease in aggregate datasets from Fall and Winter. Information about the temporal and spatial variability of modern foraminiferal distributions was formally incorporated into the Bayesian transfer function through informative foraminifera variability priors and was applied to a Common Era relative sea-level record in New Jersey. The average difference in paleomarsh elevation estimates and uncertainties using an informative vs uninformative prior was minimal (<0.01 m and 0.01 m, respectively). The dead foraminiferal assemblages remained consistent on temporal and small spatial scales, even during extreme weather events. Therefore, even when accounting for variability of modern foraminifera, foraminiferal-based relative sea-level reconstructions from high marsh environments remain robust and reproducible. |
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Asian School of the Environment |
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Asian School of the Environment Walker, Jennifer S. Cahill, Niamh Khan, Nicole S. Shaw, Timothy Adam Barber, Don Miller, Kenneth G. Kopp, Robert E. Horton, Benjamin Peter |
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Article |
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Walker, Jennifer S. Cahill, Niamh Khan, Nicole S. Shaw, Timothy Adam Barber, Don Miller, Kenneth G. Kopp, Robert E. Horton, Benjamin Peter |
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Walker, Jennifer S. |
| title |
Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
| title_short |
Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
| title_full |
Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
| title_fullStr |
Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
| title_full_unstemmed |
Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
| title_sort |
incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions |
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2022 |
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https://hdl.handle.net/10356/157204 |
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1734310196458553344 |
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sg-ntu-dr.10356-1572042022-05-14T20:11:17Z Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions Walker, Jennifer S. Cahill, Niamh Khan, Nicole S. Shaw, Timothy Adam Barber, Don Miller, Kenneth G. Kopp, Robert E. Horton, Benjamin Peter Asian School of the Environment Earth Observatory of Singapore Science::Geology Sea-Level Reconstruction Salt-Marsh Foraminifera Variability Foraminifera from salt-marsh environments have been used extensively in quantitative relative sea-level reconstructions due to their strong relationship with tidal level. However, the influence of temporal and spatial variability of salt-marsh foraminifera on quantitative reconstructions remains unconstrained. Here, we conducted a monitoring study of foraminifera from four intertidal monitoring stations in New Jersey from high marsh environments over three years that included several extreme weather (temperature, precipitation, and storm surge) events. We sampled four replicates from each station seasonally (four times per year) for a total of 188 samples. The dead foraminiferal assemblages were separated into four site-specific assemblages. After accounting for systematic trends in changes in foraminifera over time among stations, the distribution of foraminiferal assemblages across monitoring stations explained ~87% of the remaining variation, while ~13% can be explained by temporal and/or spatial variability among the replicate samples. We applied a Bayesian transfer function to estimate the elevation of the four monitoring stations. All samples from each station predicted an elevation estimate within a 95% uncertainty interval consistent with the observed elevation of that station. Combining samples into replicate- and seasonal-aggregate datasets decreased elevation estimate uncertainty, with the greatest decrease in aggregate datasets from Fall and Winter. Information about the temporal and spatial variability of modern foraminiferal distributions was formally incorporated into the Bayesian transfer function through informative foraminifera variability priors and was applied to a Common Era relative sea-level record in New Jersey. The average difference in paleomarsh elevation estimates and uncertainties using an informative vs uninformative prior was minimal (<0.01 m and 0.01 m, respectively). The dead foraminiferal assemblages remained consistent on temporal and small spatial scales, even during extreme weather events. Therefore, even when accounting for variability of modern foraminifera, foraminiferal-based relative sea-level reconstructions from high marsh environments remain robust and reproducible. Ministry of Education (MOE) National Research Foundation (NRF) Published version JSW was funded by the David and Arleen McGlade Foundation, a Cushman Foundation for Foraminiferal Research Student Research Award, and a Rutgers University Marine Field Station Graduate Student Award. JSW and REK are supported by NSF grant OCE-1804999. TAS and BPH are supported by the Singapore Ministry of Education Academic Research Fund MOE2018-T2-1-030, the National Research Foundation Singapore, and the Singapore Ministry of Education, under the Research Centers of Excellence initiative. Work by DB on this project was supported by the Harold F. Alderfer Fund for Environmental Studies at Bryn Mawr College. This article is a contribution to PALSEA (Palaeo-Constraints on Sea-Level Rise), HOLSEA and International Geoscience Program (IGCP) Project 639, “Sea-Level Changes from Minutes to Millennia”. This work comprises Earth Observatory of Singapore contribution no. 316. 2022-05-10T06:10:47Z 2022-05-10T06:10:47Z 2020 Journal Article Walker, J. S., Cahill, N., Khan, N. S., Shaw, T. A., Barber, D., Miller, K. G., Kopp, R. E. & Horton, B. P. (2020). Incorporating temporal and spatial variability of salt-marsh foraminifera into sea-level reconstructions. Marine Geology, 429, 106293-. https://dx.doi.org/10.1016/j.margeo.2020.106293 0025-3227 https://hdl.handle.net/10356/157204 10.1016/j.margeo.2020.106293 2-s2.0-85088899807 429 106293 en MOE2018-T2-1-030 Marine Geology © 2020 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/). application/pdf |