Marine biodiversity through the Late Cenomanian-Early Turonian: palaeoceanographic controls and sequence stratigraphic biases

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Journal of the Geological Society; 2000; v. 157; issue.4; p. 745-757
© 2000 Geological Society of London

Regular Article

Marine biodiversity through the Late Cenomanian–Early Turonian: palaeoceanographic controls and sequence stratigraphic biases

A. S. GALE, A. B. SMITH, N. E. A. MONKS, J. A. YOUNG, A. HOWARD, D. S. WRAY & J. M. HUGGETT

¹ School of Earth and Environmental Sciences, University of Greenwich, Medway University Campus, Chatham Maritime, Chatham, Kent ME4 4TB, UK
² Department of Palaeontology, The Natural History Museum, Cromwell Road, London SW7 5BD, UK

Scientific editing by Alistair Crame.

Changes in the marine macro- and microfauna, sedimentary geochemistryand surface-water palaeoproductivity through the last 500 000years of the Cenomanian and first 300 000 years of the Turonianare documented. These are based on the succession at Eastbourne,the thickest and most complete section through the Late Cenomanianand Early Turonian in the Anglo-Paris Basin. Two levels of rapidfaunal and geochemical change are identified, one coincidentwith a significant increase in siliciclastic input at the baseof the Plenus Marls Member, and the other with a marked dropin surface water productivity near the top of the same unit.Faunal change is demonstrated to be largely a pattern of immigration–emigrationrather than true extinction, and our sequence stratigraphicalanalysis shows that it was coincident with major sea-level changes.No evidence is found to support the hypothesis that reducedbottom water oxygenation developed and was responsible for extinctionsamongst the benthos in mid-shelf environments. The onset ofpure chalk facies is interpreted to mark the breakdown of shelf-breakfronts and the spread of oligotrophic oceanic waters over muchof the continental shelf, initiated by rising sea-level. TheCenomanian–Turonian event, far from recording a mass extinctionof shelf fauna, is most probably an artifact caused by a significantswitch in the nature of the surviving sedimentary record asa result of a major, but perfectly ordinary, oceanographic change.

Keywords: Cretaceous, anoxia, sequence stratigraphy, diversity, palaeoenvironment.

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