Hardas, Petros et al. (2012): The middle Cenomanian event in the Equatorial Atlantic; the calcareous nannofossil and benthic foraminiferal response

Leg/Site/Hole:
ODP 207
ODP 207 1260
Identifier:
2013-033440
georefid

10.1016/j.marmicro.2012.08.003
doi

Creator:
Hardas, Petros
PetroStrat, Saint Albans, United Kingdom
author

Mutterlose, Joerg
Ruhr-Universitaet Bochum, Germany
author

Friedrich, Oliver
Bundesanstalt fuer Geowissenschaften und Rohstoffe, Germany
author

Erbacher, Jochen
author

Identification:
The middle Cenomanian event in the Equatorial Atlantic; the calcareous nannofossil and benthic foraminiferal response
2012
Marine Micropaleontology
Elsevier, Amsterdam, Netherlands
96-97
66-74
In addition to Oceanic Anoxic Event 2 (OAE2), other perturbations of the carbon cycle occurred during the Cenomanian and Turonian, of which the Middle Cenomanian Event (MCE) is the most prominent one. In palaeoecological publications, however, this event is strongly underrepresented in contrast to the well-studied OAE2. In order to fill this gap, we have studied Early Cenomanian to Late Turonian calcareous nannofossil and benthic foraminiferal assemblages of Ocean Drilling Program Site 1260 at Demerara Rise (western equatorial North Atlantic), in order to decipher biotic changes throughout this interval and especially across the MCE. Our data show distinctive changes in the relative abundance of certain calcareous nannofossil taxa and a drastic decrease in benthic foraminiferal diversities and abundances associated with the MCE. In the lower part of the studied section and prior to the MCE, a mixed water-column with high nutrient availability in the upper photic zone is suggested based on very high relative abundances of the mesotrophic/eutrophic nannofossil species Biscutum constans. Around the MCE interval, certain nannofossil taxa (e.g., Rhagodiscus asper) show a distinctive decrease in relative abundance while others become more dominant. Taxa which increase in relative abundance after the MCE (e.g., Eprolithus floralis) are interpreted as either having favoured less eutrophic surface-waters or having inhabited deeper parts of the photic zone in a well stratified water-column. This interpretation is supported by published oxygen isotope and TEX (sub 86) data, which suggest increased water-column stratification starting with the MCE and lasting to the end of the Cenomanian stage, as a result of the implementation of a saline intermediate- to deep-water mass during this interval. Our study shows that the MCE was a significant biotic event in the Cenomanian/Turonian equatorial Atlantic, characterised by a lasting change of surface- and bottom-water ecosystems. Abstract Copyright (2012) Elsevier, B.V.
English
Serial
Coverage:Geographic coordinates:
North:9.1600
West:-54.3300East: -54.3300
South:9.1600

Stratigraphy; Isotope geochemistry; algae; assemblages; Atlantic Ocean; benthic taxa; biostratigraphy; Biscutum constans; C-13/C-12; carbon; carbon cycle; Cenomanian; chemostratigraphy; Cretaceous; Demerara Rise; Equatorial Atlantic; Foraminifera; geochemical cycle; Invertebrata; isotope ratios; isotopes; Leg 207; marine environment; Mesozoic; microfossils; middle Cenomanian event; nannofossils; North Atlantic; Northwest Atlantic; O-18/O-16; OAE 2; Ocean Drilling Program; oceanic anoxic events; ODP Site 1260; oxygen; paleo-oceanography; paleoclimatology; paleoecology; paleoenvironment; paleogeography; Plantae; Protista; quantitative analysis; stable isotopes; Turonian; Upper Cretaceous; West Atlantic;

.