Relation between low latitude insolation and δ 18 O change of atmospheric oxygen for the last 200 kyrs, as revealed by Mediterranean sapropels

The isotopic ratio of atmospheric O 2 , δ 18 O atm , deduced from ice cores, displays large fluctuations during climatic cycles. These are caused principally by changes in the oxygen isotopic ratio of sea‐water, δ 18 O sw , and changes in the biosphere and in the hydrological cycle. As both δ 18 O a...

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Bibliographic Details
Published in:Geophysical research letters 1997-05, Vol.24 (10), p.1235-1238
Main Authors: Mélières, M.‐A., Rossignol‐Strick, M., Malaizé, B.
Format: Article
Language:English
Subjects:
Continental interfaces, environment
Ocean, Atmosphere
Sciences of the Universe
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Summary:The isotopic ratio of atmospheric O 2 , δ 18 O atm , deduced from ice cores, displays large fluctuations during climatic cycles. These are caused principally by changes in the oxygen isotopic ratio of sea‐water, δ 18 O sw , and changes in the biosphere and in the hydrological cycle. As both δ 18 O atm and δ 18 O sw coincide closely over the last 135 kyr BP, it is generally believed that δ 18 O atm is driven mainly by δ 18 O sw . Here we focus on the major discrepancy, which arises between those two signals during the prior isotopic glacial stage 6, around 175 kyr BP, discrepancy which calls into question the role of changes in δ 18 O sw as the driving mechanism for δ 18 O atm . We present arguments, based on the occurrence and pollen content of Mediterranean sapropels, for another source of the δ 18 O atm change: insolation at low latitudes via hydrosphere/biosphere activity.
ISSN:0094-8276
1944-8007
DOI:10.1029/97GL01025