Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change

This study develops the first database of Holocene sea-level index points for the U.S. Atlantic coast using a standardized methodology. The database will help further understanding of the temporal and spatial variability in relative sea-level (RSL) rise, provide constraints on geophysical models and...

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Bibliographic Details
Main Author: Engelhart, Simon E
Other Authors: Benjamin P. Horton
Format: Thesis
Language:unknown
Published: 2010
Subjects:
sea level
salt marsh
holocene
laurentide
climate
atlantic coast
Earth Sciences
Ice Sheet
Online Access:https://repository.upenn.edu/handle/20.500.14332/31154
https://hdl.handle.net/20.500.14332/31154
id ftunivpenn:oai:repository.upenn.edu:20.500.14332/31154
record_format openpolar
spelling ftunivpenn:oai:repository.upenn.edu:20.500.14332/31154 2024-02-04T10:01:17+01:00 Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change Engelhart, Simon E Benjamin P. Horton 2010-05-17 application/pdf https://repository.upenn.edu/handle/20.500.14332/31154 https://hdl.handle.net/20.500.14332/31154 unknown https://repository.upenn.edu/handle/20.500.14332/31154 407 Publicly Accessible Penn Dissertations published sea level salt marsh holocene laurentide climate atlantic coast Earth Sciences Dissertation/Thesis 2010 ftunivpenn https://doi.org/20.500.14332/31154 2024-01-06T23:25:47Z This study develops the first database of Holocene sea-level index points for the U.S. Atlantic coast using a standardized methodology. The database will help further understanding of the temporal and spatial variability in relative sea-level (RSL) rise, provide constraints on geophysical models and document ongoing crustal movements due to Glacial Isostatic Adjustment (GIA). I sub-divided the U.S. Atlantic coast into 16 areas based on distance from the center of the Laurentide Ice Sheet. Rates of RSL change were highest during the early Holocene and have been decreasing over time, due to the continued relaxation response of the Earth’s mantle to GIA and the reduction of ice equivalent meltwater input around 7 ka. The maximum rate of RSL rise (c. 20 m since 8 ka) occurred in New Jersey and Delaware, which is subject to the greatest forebulge collapse. The rates of early Holocene (8 to 4 ka) rise were 3 - 5.5 mm a-1. I employed basal peat index points, which are subject to minimal compaction, to constrain models of GIA. I demonstrated that the current ICE-5G/6G VM5a models cannot provide a unique solution to the observations of RSL during the Holocene. I reduced the viscosity of the upper mantle by 50%, removing the discrepancy between the observations and predictions along the mid-Atlantic coastline. However, misfits still remain in Maine, northern Massachusetts and the Carolinas. Late Holocene (4 ka to present) RSL data are a proxy for crustal movements as the eustatic component was minimal during this time. Land subsidence is less than 0.8 mm a-1 in Maine, increasing to 1.7 mm a-1 in Delaware, and a return to rates lower than 0.9 mm a-1 in the Carolinas. This pattern results from the ongoing GIA due to the demise of the Laurentide Ice Sheet. I used these rates to remove the GIA component from tide gauge records to estimate a mean 20th century sea-level rise rate for the U.S. Atlantic coast of 1.8 ± 0.2 mm a-1. I identified a distinct spatial trend, increasing from Maine to South Carolina, which may be related ... Thesis Ice Sheet University of Pennsylvania: ScholaryCommons@Penn
institution Open Polar
collection University of Pennsylvania: ScholaryCommons@Penn
op_collection_id ftunivpenn
language unknown
topic sea level
salt marsh
holocene
laurentide
climate
atlantic coast
Earth Sciences
spellingShingle sea level
salt marsh
holocene
laurentide
climate
atlantic coast
Earth Sciences
Engelhart, Simon E
Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change
topic_facet sea level
salt marsh
holocene
laurentide
climate
atlantic coast
Earth Sciences
description This study develops the first database of Holocene sea-level index points for the U.S. Atlantic coast using a standardized methodology. The database will help further understanding of the temporal and spatial variability in relative sea-level (RSL) rise, provide constraints on geophysical models and document ongoing crustal movements due to Glacial Isostatic Adjustment (GIA). I sub-divided the U.S. Atlantic coast into 16 areas based on distance from the center of the Laurentide Ice Sheet. Rates of RSL change were highest during the early Holocene and have been decreasing over time, due to the continued relaxation response of the Earth’s mantle to GIA and the reduction of ice equivalent meltwater input around 7 ka. The maximum rate of RSL rise (c. 20 m since 8 ka) occurred in New Jersey and Delaware, which is subject to the greatest forebulge collapse. The rates of early Holocene (8 to 4 ka) rise were 3 - 5.5 mm a-1. I employed basal peat index points, which are subject to minimal compaction, to constrain models of GIA. I demonstrated that the current ICE-5G/6G VM5a models cannot provide a unique solution to the observations of RSL during the Holocene. I reduced the viscosity of the upper mantle by 50%, removing the discrepancy between the observations and predictions along the mid-Atlantic coastline. However, misfits still remain in Maine, northern Massachusetts and the Carolinas. Late Holocene (4 ka to present) RSL data are a proxy for crustal movements as the eustatic component was minimal during this time. Land subsidence is less than 0.8 mm a-1 in Maine, increasing to 1.7 mm a-1 in Delaware, and a return to rates lower than 0.9 mm a-1 in the Carolinas. This pattern results from the ongoing GIA due to the demise of the Laurentide Ice Sheet. I used these rates to remove the GIA component from tide gauge records to estimate a mean 20th century sea-level rise rate for the U.S. Atlantic coast of 1.8 ± 0.2 mm a-1. I identified a distinct spatial trend, increasing from Maine to South Carolina, which may be related ...
author2 Benjamin P. Horton
format Thesis
author Engelhart, Simon E
author_facet Engelhart, Simon E
author_sort Engelhart, Simon E
title Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change
title_short Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change
title_full Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change
title_fullStr Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change
title_full_unstemmed Sea-Level Changes Along the U.S. Atlantic Coast: Implications for Glacial Isostatic Adjustment Models and Current Rates of Sea-Level Change
title_sort sea-level changes along the u.s. atlantic coast: implications for glacial isostatic adjustment models and current rates of sea-level change
publishDate 2010
url https://repository.upenn.edu/handle/20.500.14332/31154
https://hdl.handle.net/20.500.14332/31154
genre Ice Sheet
genre_facet Ice Sheet
op_source 407
Publicly Accessible Penn Dissertations
published
op_relation https://repository.upenn.edu/handle/20.500.14332/31154
op_doi https://doi.org/20.500.14332/31154
_version_ 1789967038932844544

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