Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes

Beryllium isotopes measured in detrital river sediment are often used to estimate rates of landscape change at a basin scale, but results from different beryllium isotope systems have rarely been compared. Here, we report measurements of in situ and meteoric 10Be (10Bei and 10Bem, respectively) alon...

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Published in:GSA Bulletin
Main Authors: Portenga, EW, Bierman, PR, Trodick, CD, Greene, SE, DeJong, BD, Rood, DH, Pavich, MJ
Format: Article in Journal/Newspaper
Language:English
Published: Geological Society of America 2018
Subjects:
Science & Technology
Physical Sciences
Geosciences
Multidisciplinary
Geology
ATLANTIC PASSIVE-MARGIN
EASTERN-UNITED-STATES
SITU-PRODUCED BE-10
DENUDATION RATES
METEORIC BE-10
COSMOGENIC NUCLIDES
HALF-LIFE
APPALACHIAN MOUNTAINS
LANDSCAPE EVOLUTION
BAY
0403 Geology
0404 Geophysics
0402 Geochemistry
Ice Sheet
Online Access:http://hdl.handle.net/10044/1/72517
https://doi.org/10.1130/B31840.1
id ftimperialcol:oai:spiral.imperial.ac.uk:10044/1/72517
record_format openpolar
institution Open Polar
collection Imperial College London: Spiral
op_collection_id ftimperialcol
language English
topic Science & Technology
Physical Sciences
Geosciences
Multidisciplinary
Geology
ATLANTIC PASSIVE-MARGIN
EASTERN-UNITED-STATES
SITU-PRODUCED BE-10
DENUDATION RATES
METEORIC BE-10
COSMOGENIC NUCLIDES
HALF-LIFE
APPALACHIAN MOUNTAINS
LANDSCAPE EVOLUTION
BAY
0403 Geology
0404 Geophysics
0402 Geochemistry
spellingShingle Science & Technology
Physical Sciences
Geosciences
Multidisciplinary
Geology
ATLANTIC PASSIVE-MARGIN
EASTERN-UNITED-STATES
SITU-PRODUCED BE-10
DENUDATION RATES
METEORIC BE-10
COSMOGENIC NUCLIDES
HALF-LIFE
APPALACHIAN MOUNTAINS
LANDSCAPE EVOLUTION
BAY
0403 Geology
0404 Geophysics
0402 Geochemistry
Portenga, EW
Bierman, PR
Trodick, CD
Greene, SE
DeJong, BD
Rood, DH
Pavich, MJ
Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes
topic_facet Science & Technology
Physical Sciences
Geosciences
Multidisciplinary
Geology
ATLANTIC PASSIVE-MARGIN
EASTERN-UNITED-STATES
SITU-PRODUCED BE-10
DENUDATION RATES
METEORIC BE-10
COSMOGENIC NUCLIDES
HALF-LIFE
APPALACHIAN MOUNTAINS
LANDSCAPE EVOLUTION
BAY
0403 Geology
0404 Geophysics
0402 Geochemistry
description Beryllium isotopes measured in detrital river sediment are often used to estimate rates of landscape change at a basin scale, but results from different beryllium isotope systems have rarely been compared. Here, we report measurements of in situ and meteoric 10Be (10Bei and 10Bem, respectively) along with measurements of reactive and mineral phases of 9Be (9Bereac and 9Bemin, respectively) to infer long-term rates of landscape change in the Potomac River basin, North America. Using these data, we directly compare results from the two different 10Be isotope systems and contextualize modern sediment flux from the Potomac River basin to Chesapeake Bay. Sixty-two measurements of 10Bei in river sand show that the Potomac River basin is eroding on average at 29.6 ± 14.1 Mg km–2 yr–1 (11 ± 5.2 m m.y.–1 assuming a rock density of 2700 kg m–3)—a rate consistent with other estimates in the mid-Atlantic region. 10Bei erosion rates correlate with basin latitude, suggesting that periglacial weathering increased with proximity to the former Laurentide Ice Sheet margin. Considering the 10Bei-derived erosion rate as a sediment flux over millennia, rates of sediment delivery from the Potomac River to Chesapeake Bay are up to ∼5× lower than contemporary sediment yields implying modern land-use practices have accelerated erosion and sediment transport over background rates. However, 10Bei erosion rate data suggest that regulatory benchmark levels used to manage sediment export from the Potomac River basin to Chesapeake Bay are set appropriately to reduce sedimentation and restore the Bay’s ecological health. The mean of 56 10Bem/9Bereac-derived denudation rates (40.0 ± 21.7 Mg km–2 yr–1) is higher than, but statistically indistinguishable from, the mean 10Bei erosion rate (29.6 ± 14.1 Mg km–2 yr–1; p = 0.003). However, when considered basin by basin, 10Bem/9Bereac-determined denudation rates are only weakly correlated (R2 = 0.208; p < 0.001) with sediment fluxes determined from the well-established and widely used 10Bei technique. This suggests that the 10Bem/9Bereac technique may not reflect the same geomorphic processes as 10Bei technique, or that the 10Bem/9Bereac technique operates over different time and/or depth scales. Erosion indices (EIs, sensu Brown et al., 1988) derived from 10Bem measurements and contemporary sediment yield data range from 0.07 to 1.24; 75% of basins sampled have EIs that are >1, suggesting that 10Bem is being retained and sediment is being stored within the Potomac River basin. The Appalachian Plateau is the only physiographic province where sediment export dominates, likely as the result of ongoing relief growth in catchments draining the Appalachian Mountain divide. 10Bem concentrations measured in the 150 k.y. Hybla Valley sediment core, taken from the lower Potomac River basin, suggest that 10Bem and sediment are preferentially stored in the catchment when vegetation proxies for climate suggest warmer conditions prevailed. 10Bem and sediment are exported when vegetation proxies for climate suggest conditions are colder, perhaps a reflection of periglacial activity or changes in storm frequency and/or magnitude over glacial-interglacial cycles. GeoRef Subject alluvium Appalachians Central Appalachians Eastern U.S. alkaline earth metals clastic sediments Be-10/Be-9 beryllium North America Potomac River basin geomorphology isotopes isotope ratios metals sediments radioactive isotopes sand stable isotopes United States
format Article in Journal/Newspaper
author Portenga, EW
Bierman, PR
Trodick, CD
Greene, SE
DeJong, BD
Rood, DH
Pavich, MJ
author_facet Portenga, EW
Bierman, PR
Trodick, CD
Greene, SE
DeJong, BD
Rood, DH
Pavich, MJ
author_sort Portenga, EW
title Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes
title_short Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes
title_full Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes
title_fullStr Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes
title_full_unstemmed Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes
title_sort erosion rates and sediment flux within the potomac river basin quantified over millennial timescales using beryllium isotopes
publisher Geological Society of America
publishDate 2018
url http://hdl.handle.net/10044/1/72517
https://doi.org/10.1130/B31840.1
genre Ice Sheet
genre_facet Ice Sheet
op_source 1311
1295
op_relation Geological Society of America Bulletin
op_rights © 2019 Geological Society of America.
2020-02-13
op_doi https://doi.org/10.1130/B31840.1
container_title GSA Bulletin
container_volume 131
container_issue 7-8
container_start_page 1295
op_container_end_page 1311
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spelling ftimperialcol:oai:spiral.imperial.ac.uk:10044/1/72517 2023-05-15T16:41:41+02:00 Erosion rates and sediment flux within the Potomac River basin quantified over millennial timescales using beryllium isotopes Portenga, EW Bierman, PR Trodick, CD Greene, SE DeJong, BD Rood, DH Pavich, MJ 2018-12-03 http://hdl.handle.net/10044/1/72517 https://doi.org/10.1130/B31840.1 English eng Geological Society of America Geological Society of America Bulletin © 2019 Geological Society of America. 2020-02-13 1311 1295 Science & Technology Physical Sciences Geosciences Multidisciplinary Geology ATLANTIC PASSIVE-MARGIN EASTERN-UNITED-STATES SITU-PRODUCED BE-10 DENUDATION RATES METEORIC BE-10 COSMOGENIC NUCLIDES HALF-LIFE APPALACHIAN MOUNTAINS LANDSCAPE EVOLUTION BAY 0403 Geology 0404 Geophysics 0402 Geochemistry Journal Article 2018 ftimperialcol https://doi.org/10.1130/B31840.1 2019-08-15T22:37:31Z Beryllium isotopes measured in detrital river sediment are often used to estimate rates of landscape change at a basin scale, but results from different beryllium isotope systems have rarely been compared. Here, we report measurements of in situ and meteoric 10Be (10Bei and 10Bem, respectively) along with measurements of reactive and mineral phases of 9Be (9Bereac and 9Bemin, respectively) to infer long-term rates of landscape change in the Potomac River basin, North America. Using these data, we directly compare results from the two different 10Be isotope systems and contextualize modern sediment flux from the Potomac River basin to Chesapeake Bay. Sixty-two measurements of 10Bei in river sand show that the Potomac River basin is eroding on average at 29.6 ± 14.1 Mg km–2 yr–1 (11 ± 5.2 m m.y.–1 assuming a rock density of 2700 kg m–3)—a rate consistent with other estimates in the mid-Atlantic region. 10Bei erosion rates correlate with basin latitude, suggesting that periglacial weathering increased with proximity to the former Laurentide Ice Sheet margin. Considering the 10Bei-derived erosion rate as a sediment flux over millennia, rates of sediment delivery from the Potomac River to Chesapeake Bay are up to ∼5× lower than contemporary sediment yields implying modern land-use practices have accelerated erosion and sediment transport over background rates. However, 10Bei erosion rate data suggest that regulatory benchmark levels used to manage sediment export from the Potomac River basin to Chesapeake Bay are set appropriately to reduce sedimentation and restore the Bay’s ecological health. The mean of 56 10Bem/9Bereac-derived denudation rates (40.0 ± 21.7 Mg km–2 yr–1) is higher than, but statistically indistinguishable from, the mean 10Bei erosion rate (29.6 ± 14.1 Mg km–2 yr–1; p = 0.003). However, when considered basin by basin, 10Bem/9Bereac-determined denudation rates are only weakly correlated (R2 = 0.208; p < 0.001) with sediment fluxes determined from the well-established and widely used 10Bei technique. This suggests that the 10Bem/9Bereac technique may not reflect the same geomorphic processes as 10Bei technique, or that the 10Bem/9Bereac technique operates over different time and/or depth scales. Erosion indices (EIs, sensu Brown et al., 1988) derived from 10Bem measurements and contemporary sediment yield data range from 0.07 to 1.24; 75% of basins sampled have EIs that are >1, suggesting that 10Bem is being retained and sediment is being stored within the Potomac River basin. The Appalachian Plateau is the only physiographic province where sediment export dominates, likely as the result of ongoing relief growth in catchments draining the Appalachian Mountain divide. 10Bem concentrations measured in the 150 k.y. Hybla Valley sediment core, taken from the lower Potomac River basin, suggest that 10Bem and sediment are preferentially stored in the catchment when vegetation proxies for climate suggest warmer conditions prevailed. 10Bem and sediment are exported when vegetation proxies for climate suggest conditions are colder, perhaps a reflection of periglacial activity or changes in storm frequency and/or magnitude over glacial-interglacial cycles. GeoRef Subject alluvium Appalachians Central Appalachians Eastern U.S. alkaline earth metals clastic sediments Be-10/Be-9 beryllium North America Potomac River basin geomorphology isotopes isotope ratios metals sediments radioactive isotopes sand stable isotopes United States Article in Journal/Newspaper Ice Sheet Imperial College London: Spiral GSA Bulletin 131 7-8 1295 1311

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