Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation

Atlantic Meridional Overturning Circulation (AMOC) disruption during the last deglaciation is hypothesized to have caused large subsurface ocean temperature anomalies, but records from key regions are not available to test this hypothesis, and other possible drivers of warming have not been fully co...

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Published in:Paleoceanography and Paleoclimatology
Main Authors: Umling, N. E., Oppo, D. W., Chen, P., Yu, J., Liu, Z., Yan, M., Gebbie, G., Lund, D. C., Pietro, K. R., Jin, Z. D., Huang, K-F, Costa, K. B., Toledo, F. A. L.
Format: Report
Language:English
Published: AMER GEOPHYSICAL UNION 2019
Subjects:
WATER MASS GEOMETRY
ATMOSPHERIC CO2
CARBON-ISOTOPE
OCEAN CIRCULATION
NORTH-ATLANTIC
OVERTURNING CIRCULATION
BENTHIC FORAMINIFERA
INTERMEDIATE WATERS
GLACIAL MAXIMUM
CLIMATE
Geology
Oceanography
Paleontology
Geosciences
Multidisciplinary
Ice Sheet
North Atlantic
Online Access:http://ir.ieecas.cn/handle/361006/13707
https://doi.org/10.1029/2019PA003558
id ftchinacascieeca:oai:ir.ieecas.cn:361006/13707
record_format openpolar
spelling ftchinacascieeca:oai:ir.ieecas.cn:361006/13707 2023-06-11T04:12:51+02:00 Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation Umling, N. E. Oppo, D. W. Chen, P. Yu, J. Liu, Z. Yan, M. Gebbie, G. Lund, D. C. Pietro, K. R. Jin, Z. D. Huang, K-F Costa, K. B. Toledo, F. A. L. 2019-06-01 http://ir.ieecas.cn/handle/361006/13707 https://doi.org/10.1029/2019PA003558 英语 eng AMER GEOPHYSICAL UNION PALEOCEANOGRAPHY AND PALEOCLIMATOLOGY http://ir.ieecas.cn/handle/361006/13707 doi:10.1029/2019PA003558 WATER MASS GEOMETRY ATMOSPHERIC CO2 CARBON-ISOTOPE OCEAN CIRCULATION NORTH-ATLANTIC OVERTURNING CIRCULATION BENTHIC FORAMINIFERA INTERMEDIATE WATERS GLACIAL MAXIMUM CLIMATE Geology Oceanography Paleontology Geosciences Multidisciplinary 期刊论文 2019 ftchinacascieeca https://doi.org/10.1029/2019PA003558 2023-05-08T13:24:28Z Atlantic Meridional Overturning Circulation (AMOC) disruption during the last deglaciation is hypothesized to have caused large subsurface ocean temperature anomalies, but records from key regions are not available to test this hypothesis, and other possible drivers of warming have not been fully considered. Here, we present the first reliable evidence for subsurface warming in the South Atlantic during Heinrich Stadial 1, confirming the link between large-scale heat redistribution and AMOC. Warming extends across the Bolling-Allerod despite predicted cooling at this time, thus spanning intervals of both weak and strong AMOC indicating another forcing mechanism that may have been previously overlooked. Transient model simulations and quasi-conservative water mass tracers suggest that reduced northward upper ocean heat transport was responsible for the early deglacial (Heinrich Stadial 1) accumulation of heat at our shallower (similar to 1,100 m) site. In contrast, the results suggest that warming at our deeper site (similar to 1,900 m) site was dominated by southward advection of North Atlantic middepth heat anomalies. During the Bolling-Allerod, the demise of ice sheets resulted in oceanographic changes in the North Atlantic that reduced convective heat loss to the atmosphere, causing subsurface warming that overwhelmed the cooling expected from an AMOC reinvigoration. The data and simulations suggest that rising atmospheric CO2 did not contribute significantly to deglacial subsurface warming at our sites. Report Ice Sheet North Atlantic Institute of Earth Environment: IEECAS OpenIR (Chinese Academy of Sciences) Paleoceanography and Paleoclimatology 34 6 990 1005
institution Open Polar
collection Institute of Earth Environment: IEECAS OpenIR (Chinese Academy of Sciences)
op_collection_id ftchinacascieeca
language English
topic WATER MASS GEOMETRY
ATMOSPHERIC CO2
CARBON-ISOTOPE
OCEAN CIRCULATION
NORTH-ATLANTIC
OVERTURNING CIRCULATION
BENTHIC FORAMINIFERA
INTERMEDIATE WATERS
GLACIAL MAXIMUM
CLIMATE
Geology
Oceanography
Paleontology
Geosciences
Multidisciplinary
spellingShingle WATER MASS GEOMETRY
ATMOSPHERIC CO2
CARBON-ISOTOPE
OCEAN CIRCULATION
NORTH-ATLANTIC
OVERTURNING CIRCULATION
BENTHIC FORAMINIFERA
INTERMEDIATE WATERS
GLACIAL MAXIMUM
CLIMATE
Geology
Oceanography
Paleontology
Geosciences
Multidisciplinary
Umling, N. E.
Oppo, D. W.
Chen, P.
Yu, J.
Liu, Z.
Yan, M.
Gebbie, G.
Lund, D. C.
Pietro, K. R.
Jin, Z. D.
Huang, K-F
Costa, K. B.
Toledo, F. A. L.
Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation
topic_facet WATER MASS GEOMETRY
ATMOSPHERIC CO2
CARBON-ISOTOPE
OCEAN CIRCULATION
NORTH-ATLANTIC
OVERTURNING CIRCULATION
BENTHIC FORAMINIFERA
INTERMEDIATE WATERS
GLACIAL MAXIMUM
CLIMATE
Geology
Oceanography
Paleontology
Geosciences
Multidisciplinary
description Atlantic Meridional Overturning Circulation (AMOC) disruption during the last deglaciation is hypothesized to have caused large subsurface ocean temperature anomalies, but records from key regions are not available to test this hypothesis, and other possible drivers of warming have not been fully considered. Here, we present the first reliable evidence for subsurface warming in the South Atlantic during Heinrich Stadial 1, confirming the link between large-scale heat redistribution and AMOC. Warming extends across the Bolling-Allerod despite predicted cooling at this time, thus spanning intervals of both weak and strong AMOC indicating another forcing mechanism that may have been previously overlooked. Transient model simulations and quasi-conservative water mass tracers suggest that reduced northward upper ocean heat transport was responsible for the early deglacial (Heinrich Stadial 1) accumulation of heat at our shallower (similar to 1,100 m) site. In contrast, the results suggest that warming at our deeper site (similar to 1,900 m) site was dominated by southward advection of North Atlantic middepth heat anomalies. During the Bolling-Allerod, the demise of ice sheets resulted in oceanographic changes in the North Atlantic that reduced convective heat loss to the atmosphere, causing subsurface warming that overwhelmed the cooling expected from an AMOC reinvigoration. The data and simulations suggest that rising atmospheric CO2 did not contribute significantly to deglacial subsurface warming at our sites.
format Report
author Umling, N. E.
Oppo, D. W.
Chen, P.
Yu, J.
Liu, Z.
Yan, M.
Gebbie, G.
Lund, D. C.
Pietro, K. R.
Jin, Z. D.
Huang, K-F
Costa, K. B.
Toledo, F. A. L.
author_facet Umling, N. E.
Oppo, D. W.
Chen, P.
Yu, J.
Liu, Z.
Yan, M.
Gebbie, G.
Lund, D. C.
Pietro, K. R.
Jin, Z. D.
Huang, K-F
Costa, K. B.
Toledo, F. A. L.
author_sort Umling, N. E.
title Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation
title_short Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation
title_full Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation
title_fullStr Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation
title_full_unstemmed Atlantic Circulation and Ice Sheet Influences on Upper South Atlantic Temperature During the Last Deglaciation
title_sort atlantic circulation and ice sheet influences on upper south atlantic temperature during the last deglaciation
publisher AMER GEOPHYSICAL UNION
publishDate 2019
url http://ir.ieecas.cn/handle/361006/13707
https://doi.org/10.1029/2019PA003558
genre Ice Sheet
North Atlantic
genre_facet Ice Sheet
North Atlantic
op_relation PALEOCEANOGRAPHY AND PALEOCLIMATOLOGY
http://ir.ieecas.cn/handle/361006/13707
doi:10.1029/2019PA003558
op_doi https://doi.org/10.1029/2019PA003558
container_title Paleoceanography and Paleoclimatology
container_volume 34
container_issue 6
container_start_page 990
op_container_end_page 1005
_version_ 1768388980494041088

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