History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition

Following the Last Glacial Maximum (LGM; ca. 23-19 calibrated [cal.] kyr before present [BP]), atmospheric and oceanic warming, together with global sea-level rise, drove widespread deglaciation of the Antarctic Ice Sheet, increasing the flux of freshwater to the ocean and leading to substantial cha...

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Published in:Quaternary Science Reviews
Main Authors: Roseby, Zoë A., Smith, James A., Hillenbrand, Claus-Dieter, Allen, Claire S., Leventer, Amy, Hogan, Kelly, Cartigny, Matthieu J.B., Rosenheim, Brad E., Kuhn, Gerhard, Larter, Robert D.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2022
Subjects:
Antarc*
Antarctic
Antarctic Peninsula
Ice Sheet
Online Access:https://epic.awi.de/id/eprint/57256/
https://doi.org/10.1016/j.quascirev.2022.107503
https://hdl.handle.net/10013/epic.fb06808c-40fb-488d-aaa1-dc0c976b8a67
id ftawi:oai:epic.awi.de:57256
record_format openpolar
spelling ftawi:oai:epic.awi.de:57256 2024-09-15T17:41:09+00:00 History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition Roseby, Zoë A. Smith, James A. Hillenbrand, Claus-Dieter Allen, Claire S. Leventer, Amy Hogan, Kelly Cartigny, Matthieu J.B. Rosenheim, Brad E. Kuhn, Gerhard Larter, Robert D. 2022 https://epic.awi.de/id/eprint/57256/ https://doi.org/10.1016/j.quascirev.2022.107503 https://hdl.handle.net/10013/epic.fb06808c-40fb-488d-aaa1-dc0c976b8a67 unknown Roseby, Z. A. , Smith, J. A. , Hillenbrand, C. D. , Allen, C. S. , Leventer, A. , Hogan, K. , Cartigny, M. J. , Rosenheim, B. E. , Kuhn, G. orcid:0000-0001-6069-7485 and Larter, R. D. (2022) History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition , Quaternary Science Reviews, 294 , p. 107503 . doi:10.1016/j.quascirev.2022.107503 <https://doi.org/10.1016/j.quascirev.2022.107503> , hdl:10013/epic.fb06808c-40fb-488d-aaa1-dc0c976b8a67 EPIC3Quaternary Science Reviews, 294, pp. 107503, ISSN: 02773791 Article isiRev 2022 ftawi https://doi.org/10.1016/j.quascirev.2022.107503 2024-06-24T04:30:12Z Following the Last Glacial Maximum (LGM; ca. 23-19 calibrated [cal.] kyr before present [BP]), atmospheric and oceanic warming, together with global sea-level rise, drove widespread deglaciation of the Antarctic Ice Sheet, increasing the flux of freshwater to the ocean and leading to substantial changes in marine biological productivity. On the Antarctic continental shelf, periods of elevated biological productivity, often preserved in the sediment record as laminated (and sometimes varved) diatomaceous oozes (LDO), have been reported from several locations and are typically associated with the formation of calving bay re-entrants during ice sheet retreat. Understanding what drives the formation and deposition of LDOs, and the impact of deglacial processes on biogenic productivity more generally, can help inform how Antarctic coastal environments will respond to current and future ice sheet melting. In this study we utilise a suite of sediment cores recovered from Anvers-Hugo Trough (AHT), western Antarctic Peninsula shelf, which documents the transition from subglacial to glacimarine conditions following retreat of an expanded ice stream after the LGM. We present quantitative absolute diatom abundance (ADA) and species assemblage data, to investigate changes in biological productivity during the Last Glacial Transition (19-11 cal kyr BP). In combination with radiocarbon dating, we show that seasonally open marine conditions were established on the mid-shelf by 13.6 cal kyr BP, but LDOs did not start to accumulate until ∼11.5 cal kyr BP. The ∼1.4 kyr delay between the onset of seasonally open marine conditions and LDO deposition indicates that physiographic changes, and specifically the establishment of a calving bay in AHT, is insufficient to explain LDO deposition alone. LDO deposition in AHT coincides with the early Holocene climatic optimum (∼11.5 – 9.0 kyr) and is therefore explained in terms of increased atmospheric/ocean temperatures, high rates of sea and glacial ice melt and the formation of a ... Article in Journal/Newspaper Antarc* Antarctic Antarctic Peninsula Ice Sheet Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center) Quaternary Science Reviews 294 107503
institution Open Polar
collection Alfred Wegener Institute for Polar- and Marine Research (AWI): ePIC (electronic Publication Information Center)
op_collection_id ftawi
language unknown
description Following the Last Glacial Maximum (LGM; ca. 23-19 calibrated [cal.] kyr before present [BP]), atmospheric and oceanic warming, together with global sea-level rise, drove widespread deglaciation of the Antarctic Ice Sheet, increasing the flux of freshwater to the ocean and leading to substantial changes in marine biological productivity. On the Antarctic continental shelf, periods of elevated biological productivity, often preserved in the sediment record as laminated (and sometimes varved) diatomaceous oozes (LDO), have been reported from several locations and are typically associated with the formation of calving bay re-entrants during ice sheet retreat. Understanding what drives the formation and deposition of LDOs, and the impact of deglacial processes on biogenic productivity more generally, can help inform how Antarctic coastal environments will respond to current and future ice sheet melting. In this study we utilise a suite of sediment cores recovered from Anvers-Hugo Trough (AHT), western Antarctic Peninsula shelf, which documents the transition from subglacial to glacimarine conditions following retreat of an expanded ice stream after the LGM. We present quantitative absolute diatom abundance (ADA) and species assemblage data, to investigate changes in biological productivity during the Last Glacial Transition (19-11 cal kyr BP). In combination with radiocarbon dating, we show that seasonally open marine conditions were established on the mid-shelf by 13.6 cal kyr BP, but LDOs did not start to accumulate until ∼11.5 cal kyr BP. The ∼1.4 kyr delay between the onset of seasonally open marine conditions and LDO deposition indicates that physiographic changes, and specifically the establishment of a calving bay in AHT, is insufficient to explain LDO deposition alone. LDO deposition in AHT coincides with the early Holocene climatic optimum (∼11.5 – 9.0 kyr) and is therefore explained in terms of increased atmospheric/ocean temperatures, high rates of sea and glacial ice melt and the formation of a ...
format Article in Journal/Newspaper
author Roseby, Zoë A.
Smith, James A.
Hillenbrand, Claus-Dieter
Allen, Claire S.
Leventer, Amy
Hogan, Kelly
Cartigny, Matthieu J.B.
Rosenheim, Brad E.
Kuhn, Gerhard
Larter, Robert D.
spellingShingle Roseby, Zoë A.
Smith, James A.
Hillenbrand, Claus-Dieter
Allen, Claire S.
Leventer, Amy
Hogan, Kelly
Cartigny, Matthieu J.B.
Rosenheim, Brad E.
Kuhn, Gerhard
Larter, Robert D.
History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition
author_facet Roseby, Zoë A.
Smith, James A.
Hillenbrand, Claus-Dieter
Allen, Claire S.
Leventer, Amy
Hogan, Kelly
Cartigny, Matthieu J.B.
Rosenheim, Brad E.
Kuhn, Gerhard
Larter, Robert D.
author_sort Roseby, Zoë A.
title History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition
title_short History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition
title_full History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition
title_fullStr History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition
title_full_unstemmed History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition
title_sort history of anvers-hugo trough, western antarctic peninsula shelf, since the last glacial maximum. part ii: palaeo-productivity and palaeoceanographic changes during the last glacial transition
publishDate 2022
url https://epic.awi.de/id/eprint/57256/
https://doi.org/10.1016/j.quascirev.2022.107503
https://hdl.handle.net/10013/epic.fb06808c-40fb-488d-aaa1-dc0c976b8a67
genre Antarc*
Antarctic
Antarctic Peninsula
Ice Sheet
genre_facet Antarc*
Antarctic
Antarctic Peninsula
Ice Sheet
op_source EPIC3Quaternary Science Reviews, 294, pp. 107503, ISSN: 02773791
op_relation Roseby, Z. A. , Smith, J. A. , Hillenbrand, C. D. , Allen, C. S. , Leventer, A. , Hogan, K. , Cartigny, M. J. , Rosenheim, B. E. , Kuhn, G. orcid:0000-0001-6069-7485 and Larter, R. D. (2022) History of Anvers-Hugo Trough, western Antarctic Peninsula shelf, since the Last Glacial Maximum. Part II: Palaeo-productivity and palaeoceanographic changes during the Last Glacial Transition , Quaternary Science Reviews, 294 , p. 107503 . doi:10.1016/j.quascirev.2022.107503 <https://doi.org/10.1016/j.quascirev.2022.107503> , hdl:10013/epic.fb06808c-40fb-488d-aaa1-dc0c976b8a67
op_doi https://doi.org/10.1016/j.quascirev.2022.107503
container_title Quaternary Science Reviews
container_volume 294
container_start_page 107503
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