Sexton, Philip F. and Barker, Stephen (2012): Onset of 'Pacific-style' deep-sea sedimentary carbonate cycles at the mid-Pleistocene transition

Leg/Site/Hole:
ODP 130
ODP 138
ODP 181
ODP 202
DSDP 94
DSDP 94 607
ODP 181 1123
ODP 202 1241
ODP 130 806
ODP 138 846
ODP 138 849
Identifier:
2012-054089
georefid

10.1016/j.epsl.2011.12.043
doi

Creator:
Sexton, Philip F.
Open University, Centre for Earth, Planetary, Space and Astronomical Research, Milton Keynes, United Kingdom
author

Barker, Stephen
Cardiff University
author

Identification:
Onset of 'Pacific-style' deep-sea sedimentary carbonate cycles at the mid-Pleistocene transition
2012
Earth and Planetary Science Letters
Elsevier, Amsterdam, Netherlands
321-322
81-94
The calcium carbonate (CaCO (sub 3) ) content of deep-sea sediments in the Pacific Ocean increases during glacials of the late Pleistocene in comparison to interglacials, whereas records of sedimentary CaCO (sub 3) in the Atlantic Ocean show an anticorrelated pattern across glacial-interglacial cycles. Here we show that this anticorrelation in inter-ocean CaCO (sub 3) cycles arose comparatively recently, at approximately 1.10 million years ago (Ma), during the mid-Pleistocene transition. Before this time, we show that the CaCO (sub 3) content of Pacific and Atlantic Ocean sediments experienced in-phase cyclicity, both having 'Atlantic-style' phasing with respect to glacial-interglacial cycles. The onset of anticorrelated cyclicity at 1.10 Ma involved a twofold switch in the Pacific's CaCO (sub 3) cycles: glacial CaCO (sub 3) preservation became consistently better while interglacial preservation became consistently worse. We demonstrate that the cause of this glacial-interglacial 'mirror imaging' of Pacific CaCO (sub 3) dissolution cyclicity at 1.10 Ma was a switching over of the relative ventilation state of abyssal South Pacific waters between glacials and interglacials. Specifically, we suggest that a consistent strengthening of deep water ventilation within the Pacific sector of the Southern Ocean during glacials drove glacial Pacific CaCO (sub 3) dissolution to diminish, while a contemporaneous weakening of very well-ventilated 'upstream' North Atlantic Deep Water during interglacials drove interglacial Pacific CaCO (sub 3) dissolution 'downstream' to intensify. We propose that the increased mean alkalinity of the global deep ocean (driven by the geographically and bathymetrically vast Pacific Ocean) during glacials after 1.10 Ma may explain part of the drawdown in glacial atmospheric CO (sub 2) levels hypothesised to have been linked to the increased severity of these late Pleistocene glacials. Abstract Copyright (2012) Elsevier, B.V.
English
Serial
Coverage:Geographic coordinates:
North:41.0005
West:-90.4906East: 159.2142
South:-3.0549

Quaternary geology; alkalinity; Atlantic Ocean; calcium carbonate; carbonates; Cenozoic; Chatham Rise; Cocos Ridge; cyclic processes; Deep Sea Drilling Project; deep-sea environment; DSDP Site 607; East Pacific; Equatorial Pacific; glacial environment; Holocene; interglacial environment; IPOD; Leg 130; Leg 138; Leg 181; Leg 202; Leg 94; marine environment; marine sediments; Mid-Atlantic Ridge; middle Pleistocene; North Atlantic; North Pacific; Northeast Atlantic; Northeast Pacific; Northwest Pacific; ocean circulation; Ocean Drilling Program; ODP Site 1123; ODP Site 1241; ODP Site 806; ODP Site 846; ODP Site 849; Ontong Java Plateau; Pacific Ocean; Pleistocene; Quaternary; sea-level changes; sediments; South Pacific; Southeast Pacific; ventilation; West Pacific;

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