Fish tooth δ18O revising Late Cretaceous meridional upper ocean water temperature gradients

The oxygen isotope composition of fossil fish teeth, a paleo-upper ocean temperature proxy exceptionally resistant to diagenetic alteration, provides new insight on the evolution of the low- to middle-latitude thermal gradient between the middle Cretaceous climatic optimum and the cooler latest Cret...

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Bibliographic Details
Published in:Geology (Boulder) 2007, Vol.35 (2), p.107-110
Main Authors: Pucéat, Emmanuelle, Lécuyer, Christophe, Donnadieu, Yannick, Naveau, Philippe, Cappetta, Henri, Ramstein, Gilles, Huber, Brian T, Kriwet, Juergen
Format: Article
Language:English
Subjects:
apatite
biochemistry
carbon dioxide
Chondrichthyes
Chordata
cooling
correlation
Cretaceous
Earth Sciences
Environmental Sciences
Foraminifera
Geochemistry
geothermal gradient
global
Global Changes
Invertebrata
isotope ratios
isotopes
Lamniformes
marine environment
Mesozoic
microfossils
O-18/O-16
oxygen
paleo-oceanography
paleoatmosphere
paleoclimatology
paleolatitude
paleotemperature
phosphates
Pisces
planktonic taxa
Protista
Sciences of the Universe
stable isotopes
statistical analysis
Stratigraphy
teeth
thermal history
Upper Cretaceous
Vertebrata
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Summary:The oxygen isotope composition of fossil fish teeth, a paleo-upper ocean temperature proxy exceptionally resistant to diagenetic alteration, provides new insight on the evolution of the low- to middle-latitude thermal gradient between the middle Cretaceous climatic optimum and the cooler latest Cretaceous period. The new middle Cretaceous low to middle latitude thermal gradient agrees with that previously inferred from planktonic foraminifera δ18O recovered from Deep Sea Drilling Project and Ocean Drilling Program drilling sites, although the isotopic temperatures derived from δ18O of fish teeth are uniformly higher by ∼3-4°C. In contrast, our new latest Cretaceous thermal gradient is markedly steeper than those previously published for this period. Fish tooth δ18O data demonstrate that low- to middle-latitude thermal gradients of the middle Cretaceous climatic optimum and of the cooler latest Cretaceous are similar to the modern one, despite a cooling of 7 °C between the two periods. Our new results imply that no drastic changes in meridional heat transport are required to explain the Late Cretaceous climate. Based on climate models, such a cooling without any change in the low- to middle-latitude thermal gradient supports an atmospheric CO2 as the primary driver of the climatic evolution recorded during the Late Cretaceous.
ISSN:0091-7613
1943-2682
DOI:10.1130/G23103A.1