Sea-level change during the last 2500 years in New Jersey, USA

Andrew C. Kemp; Benjamin P. Horton; Christopher H. Vane; Christopher E. Bernhardt; D. Reide Corbett; Simon E. Engelhart; Shimon C. Anisfeld; Andrew C. Parnell; Niamh Cahill

doi:10.1016/j.quascirev.2013.09.024

Sea-level change during the last 2500 years in New Jersey, USA

Andrew C. Kemp, Benjamin P. Horton, Christopher H. Vane, Christopher E. Bernhardt, D. Reide Corbett, Simon E. Engelhart, Shimon C. Anisfeld, Andrew C. Parnell, Niamh Cahill

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

89 Citations (Scopus)

Abstract

Relative sea-level changes during the last ~2500 years in New Jersey, USA were reconstructed to test if late Holocene sea level was stable or included persistent and distinctive phases of variability. Foraminifera and bulk-sediment δ¹³C values were combined to reconstruct paleomarsh elevation with decimeter precision from sequences of salt-marsh sediment at two sites using a multi-proxy approach. The additional paleoenvironmental information provided by bulk-sediment δ¹³C values reduced vertical uncertainty in the sea-level reconstruction by about one third of that estimated from foraminifera alone using a transfer function. The history of sediment deposition was constrained by a composite chronology. An age-depth model developed for each core enabled reconstruction of sea level with multi-decadal resolution. Following correction for land-level change (1.4mm/yr), four successive and sustained (multi-centennial) sea-level trends were objectively identified and quantified (95% confidence interval) using error-in-variables change point analysis to account for age and sea-level uncertainties. From at least 500BC to 250AD, sea-level fell at 0.11mm/yr. The second period saw sea-level rise at 0.62mm/yr from 250AD to 733AD. Between 733AD and 1850AD, sea level fell at 0.12mm/yr. The reconstructed rate of sea-level rise since ~1850AD was 3.1mm/yr and represents the most rapid period of change for at least 2500 years. This trend began between 1830AD and 1873AD. Since this change point, reconstructed sea-level rise is in agreement with regional tide-gauge records and exceeds the global average estimate for the 20th century. These positive and negative departures from background rates demonstrate that the late Holocene sea level was not stable in New Jersey. © 2013 Elsevier Ltd.

Original language	English
Pages (from-to)	90-104
Journal	Quaternary Science Reviews
Volume	81
DOIs	https://doi.org/10.1016/j.quascirev.2013.09.024
Publication status	Published - 1 Dec 2013
Externally published	Yes

Bibliographical note

Publication details (e.g. title, author(s), publication statuses and dates) are captured on an “AS IS” and “AS AVAILABLE” basis at the time of record harvesting from the data source. Suggestions for further amendments or supplementary information can be sent to [email protected].

Funding

This work was supported by National Oceanic and Atmospheric Administration award NA11OAR4310101 and NSF grants EAR-1052848 and EAR-0951686 . Kemp thanks a graduate student internship at NOSAMS that provided radiocarbon dating under the supervision of Dr. Mark Roberts. Vane publishes with permission of the director of the British Geological Survey who partially supported this work through the BGS Climate and Landscape research program. We thank the Edwin Forsythe National Wildlife Refuge (U.S. Fish and Wildlife Service) for granting access and student volunteers from the Earthwatch Student Challenge Award Program for their enthusiastic help for in fieldwork. We thank Daria Nikitina, Nicole Khan, Jessica Pilarczyk, and Andrea Hawkes for their assistance in the field and in the lab. W.R. Peltier and R. Drummond kindly provided the Earth-Ice model predictions for the study sites. This is a contribution to PALSEA and IGCP Project 588 \u201CPreparing for Coastal Change\u201D. The manuscript benefited from the thoughtful and productive comments of Tom Cronin (USGS) and two anonymous reviewers.

Research Keywords

20th Century
Foraminifera
Little Ice Age
Medieval Climate Anomaly
Salt-marsh
Transfer function

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title = "Sea-level change during the last 2500 years in New Jersey, USA",

abstract = "Relative sea-level changes during the last ~2500 years in New Jersey, USA were reconstructed to test if late Holocene sea level was stable or included persistent and distinctive phases of variability. Foraminifera and bulk-sediment δ13C values were combined to reconstruct paleomarsh elevation with decimeter precision from sequences of salt-marsh sediment at two sites using a multi-proxy approach. The additional paleoenvironmental information provided by bulk-sediment δ13C values reduced vertical uncertainty in the sea-level reconstruction by about one third of that estimated from foraminifera alone using a transfer function. The history of sediment deposition was constrained by a composite chronology. An age-depth model developed for each core enabled reconstruction of sea level with multi-decadal resolution. Following correction for land-level change (1.4mm/yr), four successive and sustained (multi-centennial) sea-level trends were objectively identified and quantified (95% confidence interval) using error-in-variables change point analysis to account for age and sea-level uncertainties. From at least 500BC to 250AD, sea-level fell at 0.11mm/yr. The second period saw sea-level rise at 0.62mm/yr from 250AD to 733AD. Between 733AD and 1850AD, sea level fell at 0.12mm/yr. The reconstructed rate of sea-level rise since ~1850AD was 3.1mm/yr and represents the most rapid period of change for at least 2500 years. This trend began between 1830AD and 1873AD. Since this change point, reconstructed sea-level rise is in agreement with regional tide-gauge records and exceeds the global average estimate for the 20th century. These positive and negative departures from background rates demonstrate that the late Holocene sea level was not stable in New Jersey. {\textcopyright} 2013 Elsevier Ltd.",

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AU - Horton, Benjamin P.

AU - Vane, Christopher H.

AU - Bernhardt, Christopher E.

AU - Corbett, D. Reide

AU - Engelhart, Simon E.

AU - Anisfeld, Shimon C.

AU - Parnell, Andrew C.

AU - Cahill, Niamh

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N2 - Relative sea-level changes during the last ~2500 years in New Jersey, USA were reconstructed to test if late Holocene sea level was stable or included persistent and distinctive phases of variability. Foraminifera and bulk-sediment δ13C values were combined to reconstruct paleomarsh elevation with decimeter precision from sequences of salt-marsh sediment at two sites using a multi-proxy approach. The additional paleoenvironmental information provided by bulk-sediment δ13C values reduced vertical uncertainty in the sea-level reconstruction by about one third of that estimated from foraminifera alone using a transfer function. The history of sediment deposition was constrained by a composite chronology. An age-depth model developed for each core enabled reconstruction of sea level with multi-decadal resolution. Following correction for land-level change (1.4mm/yr), four successive and sustained (multi-centennial) sea-level trends were objectively identified and quantified (95% confidence interval) using error-in-variables change point analysis to account for age and sea-level uncertainties. From at least 500BC to 250AD, sea-level fell at 0.11mm/yr. The second period saw sea-level rise at 0.62mm/yr from 250AD to 733AD. Between 733AD and 1850AD, sea level fell at 0.12mm/yr. The reconstructed rate of sea-level rise since ~1850AD was 3.1mm/yr and represents the most rapid period of change for at least 2500 years. This trend began between 1830AD and 1873AD. Since this change point, reconstructed sea-level rise is in agreement with regional tide-gauge records and exceeds the global average estimate for the 20th century. These positive and negative departures from background rates demonstrate that the late Holocene sea level was not stable in New Jersey. © 2013 Elsevier Ltd.

AB - Relative sea-level changes during the last ~2500 years in New Jersey, USA were reconstructed to test if late Holocene sea level was stable or included persistent and distinctive phases of variability. Foraminifera and bulk-sediment δ13C values were combined to reconstruct paleomarsh elevation with decimeter precision from sequences of salt-marsh sediment at two sites using a multi-proxy approach. The additional paleoenvironmental information provided by bulk-sediment δ13C values reduced vertical uncertainty in the sea-level reconstruction by about one third of that estimated from foraminifera alone using a transfer function. The history of sediment deposition was constrained by a composite chronology. An age-depth model developed for each core enabled reconstruction of sea level with multi-decadal resolution. Following correction for land-level change (1.4mm/yr), four successive and sustained (multi-centennial) sea-level trends were objectively identified and quantified (95% confidence interval) using error-in-variables change point analysis to account for age and sea-level uncertainties. From at least 500BC to 250AD, sea-level fell at 0.11mm/yr. The second period saw sea-level rise at 0.62mm/yr from 250AD to 733AD. Between 733AD and 1850AD, sea level fell at 0.12mm/yr. The reconstructed rate of sea-level rise since ~1850AD was 3.1mm/yr and represents the most rapid period of change for at least 2500 years. This trend began between 1830AD and 1873AD. Since this change point, reconstructed sea-level rise is in agreement with regional tide-gauge records and exceeds the global average estimate for the 20th century. These positive and negative departures from background rates demonstrate that the late Holocene sea level was not stable in New Jersey. © 2013 Elsevier Ltd.

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KW - Foraminifera

KW - Little Ice Age

KW - Medieval Climate Anomaly

KW - Salt-marsh

KW - Transfer function

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SN - 0277-3791

VL - 81

SP - 90

EP - 104

JO - Quaternary Science Reviews

JF - Quaternary Science Reviews

ER -

Sea-level change during the last 2500 years in New Jersey, USA

Abstract

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Research Keywords

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