Evidence for a heavily glaciated Antarctica during the late Oligocene “warming” (27.8–24.5 Ma): Stable isotope records from ODP Site 690

Evidence for a heavily glaciated Antarctica during the late Oligocene “warming” (27.8–24.5 Ma): Stable isotope records from ODP Site 690

High δ18O values (> 3.0‰) from a 9 kyr resolution benthic foraminiferal stable isotope record from the Ocean Drilling Program hole 690B located on the Maud Rise, Antarctica, indicate a heavily glaciated Antarctic continent during late Oligocene (27.8–24.5 Ma). Values ranging 2.5–3.0‰ during inter...

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Veröffentlicht in:Paleoceanography 2017-04, Vol.32 (4), p.384-396
Hauptverfasser: Hauptvogel, D. W., Pekar, S. F., Pincay, V.
Format: Artikel
Sprache:eng
Schlagworte:
Antarctic glaciation
Antarctica
Basins
Boreholes
Climate change
Coasts
Collapse
Deep sea
Deep water
Drilling
Glacial periods
Glaciation
Glaciers
Glaciology
Global warming
Ice
Ice sheets
Interglacial periods
Isotopes
late Oligocene
Latitude
Masking
Ocean basins
Ocean Drilling Program (ODP)
Oligocene
Oxygen
Oxygen isotopes
Paleoclimate science
Sea level
Stable isotopes
Warm water mass formation
Water temperature
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Pincay, V.
description High δ18O values (> 3.0‰) from a 9 kyr resolution benthic foraminiferal stable isotope record from the Ocean Drilling Program hole 690B located on the Maud Rise, Antarctica, indicate a heavily glaciated Antarctic continent during late Oligocene (27.8–24.5 Ma). Values ranging 2.5–3.0‰ during interglacial periods and 3.0–3.6‰ during glacial intervals are consistent with an ice sheet near or larger than modern size. In addition, this record does not exhibit the long‐term late Oligocene warming trend seen in records from low‐latitude drill sites. Oxygen isotope values from 26.0 to 24.5 Ma are comparable (ranging between 2.5 and 3.3‰) to values that preceded the δ18O event Oi2b at 26.7 Ma, indicating no significant glacial collapse occurred during the late Oligocene. A gradient between ocean basins during the Oligocene has already been linked to the development of a modern, multilayered ocean and worked to bathe the low latitude to midlatitude, deep‐sea records with a warmer water mass. We suggest that this masked the significant Antarctic glaciation in low‐latitude paleoceanographic records. Additionally, we propose a resolution for conflicting lines of evidence from some Antarctic proximal records suggesting significant glaciation and others suggesting reduced glaciation during the late Oligocene by allowing a modern‐sized ice sheet to grow on an Antarctic continent as more land surface area existed above sea level during this time. This could allow at least some portions of the Antarctic coastline to remain ice‐free during glacial minima while still maintaining modern or near‐modern ice volume. Key Points Antarctic proximal oxygen isotope record reflects a large ice sheet during the late Oligocene Significant amount of ice in West Antarctica during the late Oligocene Low‐latitude isotope records influenced by a water mass that is masking Antarctic glaciation
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In addition, this record does not exhibit the long‐term late Oligocene warming trend seen in records from low‐latitude drill sites. Oxygen isotope values from 26.0 to 24.5 Ma are comparable (ranging between 2.5 and 3.3‰) to values that preceded the δ18O event Oi2b at 26.7 Ma, indicating no significant glacial collapse occurred during the late Oligocene. A gradient between ocean basins during the Oligocene has already been linked to the development of a modern, multilayered ocean and worked to bathe the low latitude to midlatitude, deep‐sea records with a warmer water mass. We suggest that this masked the significant Antarctic glaciation in low‐latitude paleoceanographic records. Additionally, we propose a resolution for conflicting lines of evidence from some Antarctic proximal records suggesting significant glaciation and others suggesting reduced glaciation during the late Oligocene by allowing a modern‐sized ice sheet to grow on an Antarctic continent as more land surface area existed above sea level during this time. This could allow at least some portions of the Antarctic coastline to remain ice‐free during glacial minima while still maintaining modern or near‐modern ice volume. Key Points Antarctic proximal oxygen isotope record reflects a large ice sheet during the late Oligocene Significant amount of ice in West Antarctica during the late Oligocene Low‐latitude isotope records influenced by a water mass that is masking Antarctic glaciation</abstract><cop>Washington</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1002/2016PA002972</doi><tpages>13</tpages><orcidid>https://orcid.org/0000-0003-2465-0596</orcidid><orcidid>https://orcid.org/0000-0001-7742-9719</orcidid><oa>free_for_read</oa></addata></record>
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identifier ISSN: 0883-8305
ispartof Paleoceanography, 2017-04, Vol.32 (4), p.384-396
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source Wiley Journals; Wiley-Blackwell AGU Digital Library; Wiley Online Library (Open Access Collection)
subjects Antarctic glaciation
Antarctica
Basins
Boreholes
Climate change
Coasts
Collapse
Deep sea
Deep water
Drilling
Glacial periods
Glaciation
Glaciers
Glaciology
Global warming
Ice
Ice sheets
Interglacial periods
Isotopes
late Oligocene
Latitude
Masking
Ocean basins
Ocean Drilling Program (ODP)
Oligocene
Oxygen
Oxygen isotopes
Paleoclimate science
Sea level
Stable isotopes
Warm water mass formation
Water temperature
title Evidence for a heavily glaciated Antarctica during the late Oligocene “warming” (27.8–24.5 Ma): Stable isotope records from ODP Site 690
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