Relative sea-level change in South Florida during the past ~5000 years

Nicole S. Khan; Erica Ashe; Ryan P. Moyer; Andrew C. Kemp; Simon E. Engelhart; Matthew J. Brain; Lauren T. Toth; Amanda Chappel; Margaret Christie; Robert E. Kopp; Benjamin P. Horton

doi:10.1016/j.gloplacha.2022.103902

Relative sea-level change in South Florida during the past ~5000 years

Nicole S. Khan^*, Erica Ashe, Ryan P. Moyer, Andrew C. Kemp, Simon E. Engelhart, Matthew J. Brain, Lauren T. Toth, Amanda Chappel, Margaret Christie, Robert E. Kopp, Benjamin P. Horton

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

13 Citations (Scopus)

Abstract

A paucity of detailed relative sea-level (RSL) reconstructions from low latitudes hinders efforts to understand the global, regional, and local processes that cause RSL change. We reconstruct RSL change during the past ~5 ka using cores of mangrove peat at two sites (Snipe Key and Swan Key) in the Florida Keys. Remote sensing and field surveys established the relationship between peat-forming mangroves and tidal elevation in South Florida. Core chronologies are developed from age-depth models applied to 72 radiocarbon dates (39 mangrove wood macrofossils and 33 fine-fraction bulk peat). RSL rose 3.7 m at Snipe Key and 5.0 m at Swan Key in the past 5 ka, with both sites recording the fastest century-scale rate of RSL rise since ~1900 CE (~2.1 mm/a). We demonstrate that it is feasible to produce near-continuous reconstructions of RSL from mangrove peat in regions with a microtidal regime and accommodation space created by millennial-scale RSL rise. Decomposition of RSL trends from a network of reconstructions across South Florida using a spatio-temporal model suggests that Snipe Key was representative of regional RSL trends, but Swan Key was influenced by an additional local-scale process acting over at least the past five millennia. Geotechnical analysis of modern and buried mangrove peat indicates that sediment compaction is not the local-scale process responsible for the exaggerated RSL rise at Swan Key. The substantial difference in RSL between two nearby sites highlights the critical need for within-region replication of RSL reconstructions to avoid misattribution of sea-level trends, which could also have implications for geophysical modeling studies using RSL data for model tuning and validation. © 2022 Published by Elsevier B.V.

Original language	English
Article number	103902
Journal	Global and Planetary Change
Volume	216
Online published	30 Jul 2022
DOIs	https://doi.org/10.1016/j.gloplacha.2022.103902
Publication status	Published - Sept 2022
Externally published	Yes

Funding

This work was supported by the Coastal and Marine Hazards and Resources Program and the Natural Hazards Mission Area, the Climate Research and Development Program of U.S. Geological Survey . Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government. We thank Jaimie Shaw, Paulina Capar, and Anastasios Stathakapolous for assistance in the laboratory and field. Site access and research permission were provided by K. Watts for the Florida Keys National Wildlife Refuges Complex (Special Use Permit #FFO4RFKD-2015-020 ). Authors were supported by National Science Foundation Awards ( OCE-1702587 , OCE-1831450 , and OCE-2002437 to Kopp and Ashe; OCE-2002431 , OCE-1458921 , OCE-1831382 , and OCE-1942563 to Kemp; OCE-1458903 to Engelhart). RPM is supported by the US Fish and Wildlife Service's State Wildlife Grants Program ( #F13AF00982 ). BPH is supported by the Singapore Ministry of Education Academic Research Fund MOE2019-T3-1-004 and MOE-T2EP50120-0007 , the National Research Foundation Singapore , the Singapore Ministry of Education under the Research Centers of Excellence Initiative . Radiocarbon ages and descriptive core logs from SNK1 and SBC10 are available in a U.S. Geological Survey Data Release ( https://doi.org/10.5066/P9OOL3L4 ). Data produced by non-USGS contributors are available upon request. This paper is a contribution to IGCP project 639 “Sea-level change from minutes to millennia,” IGCP project 725 “Forecasting Coastal Change: From Cores to Code,” PALSEA, and INQUA project 1601 “Geographic variability of Holocene relative sea level”. This work comprises Earth Observatory of Singapore contribution no. 459.

Research Keywords

Holocene
Mangrove
Proxy reconstruction
Reproducibility
Sea level

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title = "Relative sea-level change in South Florida during the past ~5000 years",

abstract = "A paucity of detailed relative sea-level (RSL) reconstructions from low latitudes hinders efforts to understand the global, regional, and local processes that cause RSL change. We reconstruct RSL change during the past ~5 ka using cores of mangrove peat at two sites (Snipe Key and Swan Key) in the Florida Keys. Remote sensing and field surveys established the relationship between peat-forming mangroves and tidal elevation in South Florida. Core chronologies are developed from age-depth models applied to 72 radiocarbon dates (39 mangrove wood macrofossils and 33 fine-fraction bulk peat). RSL rose 3.7 m at Snipe Key and 5.0 m at Swan Key in the past 5 ka, with both sites recording the fastest century-scale rate of RSL rise since ~1900 CE (~2.1 mm/a). We demonstrate that it is feasible to produce near-continuous reconstructions of RSL from mangrove peat in regions with a microtidal regime and accommodation space created by millennial-scale RSL rise. Decomposition of RSL trends from a network of reconstructions across South Florida using a spatio-temporal model suggests that Snipe Key was representative of regional RSL trends, but Swan Key was influenced by an additional local-scale process acting over at least the past five millennia. Geotechnical analysis of modern and buried mangrove peat indicates that sediment compaction is not the local-scale process responsible for the exaggerated RSL rise at Swan Key. The substantial difference in RSL between two nearby sites highlights the critical need for within-region replication of RSL reconstructions to avoid misattribution of sea-level trends, which could also have implications for geophysical modeling studies using RSL data for model tuning and validation. {\textcopyright} 2022 Published by Elsevier B.V.",

keywords = "Holocene, Mangrove, Proxy reconstruction, Reproducibility, Sea level",

author = "Khan, {Nicole S.} and Erica Ashe and Moyer, {Ryan P.} and Kemp, {Andrew C.} and Engelhart, {Simon E.} and Brain, {Matthew J.} and Toth, {Lauren T.} and Amanda Chappel and Margaret Christie and Kopp, {Robert E.} and Horton, {Benjamin P.}",

year = "2022",

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doi = "10.1016/j.gloplacha.2022.103902",

language = "English",

volume = "216",

journal = "Global and Planetary Change",

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T1 - Relative sea-level change in South Florida during the past ~5000 years

AU - Khan, Nicole S.

AU - Ashe, Erica

AU - Moyer, Ryan P.

AU - Kemp, Andrew C.

AU - Engelhart, Simon E.

AU - Brain, Matthew J.

AU - Toth, Lauren T.

AU - Chappel, Amanda

AU - Christie, Margaret

AU - Kopp, Robert E.

AU - Horton, Benjamin P.

PY - 2022/9

Y1 - 2022/9

N2 - A paucity of detailed relative sea-level (RSL) reconstructions from low latitudes hinders efforts to understand the global, regional, and local processes that cause RSL change. We reconstruct RSL change during the past ~5 ka using cores of mangrove peat at two sites (Snipe Key and Swan Key) in the Florida Keys. Remote sensing and field surveys established the relationship between peat-forming mangroves and tidal elevation in South Florida. Core chronologies are developed from age-depth models applied to 72 radiocarbon dates (39 mangrove wood macrofossils and 33 fine-fraction bulk peat). RSL rose 3.7 m at Snipe Key and 5.0 m at Swan Key in the past 5 ka, with both sites recording the fastest century-scale rate of RSL rise since ~1900 CE (~2.1 mm/a). We demonstrate that it is feasible to produce near-continuous reconstructions of RSL from mangrove peat in regions with a microtidal regime and accommodation space created by millennial-scale RSL rise. Decomposition of RSL trends from a network of reconstructions across South Florida using a spatio-temporal model suggests that Snipe Key was representative of regional RSL trends, but Swan Key was influenced by an additional local-scale process acting over at least the past five millennia. Geotechnical analysis of modern and buried mangrove peat indicates that sediment compaction is not the local-scale process responsible for the exaggerated RSL rise at Swan Key. The substantial difference in RSL between two nearby sites highlights the critical need for within-region replication of RSL reconstructions to avoid misattribution of sea-level trends, which could also have implications for geophysical modeling studies using RSL data for model tuning and validation. © 2022 Published by Elsevier B.V.

AB - A paucity of detailed relative sea-level (RSL) reconstructions from low latitudes hinders efforts to understand the global, regional, and local processes that cause RSL change. We reconstruct RSL change during the past ~5 ka using cores of mangrove peat at two sites (Snipe Key and Swan Key) in the Florida Keys. Remote sensing and field surveys established the relationship between peat-forming mangroves and tidal elevation in South Florida. Core chronologies are developed from age-depth models applied to 72 radiocarbon dates (39 mangrove wood macrofossils and 33 fine-fraction bulk peat). RSL rose 3.7 m at Snipe Key and 5.0 m at Swan Key in the past 5 ka, with both sites recording the fastest century-scale rate of RSL rise since ~1900 CE (~2.1 mm/a). We demonstrate that it is feasible to produce near-continuous reconstructions of RSL from mangrove peat in regions with a microtidal regime and accommodation space created by millennial-scale RSL rise. Decomposition of RSL trends from a network of reconstructions across South Florida using a spatio-temporal model suggests that Snipe Key was representative of regional RSL trends, but Swan Key was influenced by an additional local-scale process acting over at least the past five millennia. Geotechnical analysis of modern and buried mangrove peat indicates that sediment compaction is not the local-scale process responsible for the exaggerated RSL rise at Swan Key. The substantial difference in RSL between two nearby sites highlights the critical need for within-region replication of RSL reconstructions to avoid misattribution of sea-level trends, which could also have implications for geophysical modeling studies using RSL data for model tuning and validation. © 2022 Published by Elsevier B.V.

KW - Holocene

KW - Mangrove

KW - Proxy reconstruction

KW - Reproducibility

KW - Sea level

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DO - 10.1016/j.gloplacha.2022.103902

M3 - RGC 21 - Publication in refereed journal

SN - 0921-8181

VL - 216

JO - Global and Planetary Change

JF - Global and Planetary Change

M1 - 103902

ER -

Relative sea-level change in South Florida during the past ~5000 years

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