The sedimentology and depositional environment of the Crato Formation

doi:10.1017/CBO9780511535512.005

4 - The sedimentology and depositional environment of the Crato Formation

Published online by Cambridge University Press: 22 August 2009

Günter Bechly and

Ulrich Heimhofer and

David M. Martill: Affiliation:
University of Portsmouth
Günter Bechly: Affiliation:
Staatliches Museum für Naturkunde, Stuttgart
Robert F. Loveridge: Affiliation:
University of Portsmouth
Ulrich Heimhofer: Affiliation:
Ruhr-Universität Bochum, Institute for Geology, Mineralogy and Geophysics, Sedimentary and Isotope Geology, Universitätsstr, Germany
David M. Martill: Affiliation:
Reader in Palaeobiology in the School of Earth and Environmental Sciences, University of Portsmouth

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Summary

Although the exceptionally preserved fossils from the Crato Formation have attracted a multitude of palaeontological studies dealing predominantly with the systematics and taxonomy of the assemblage, reports on the sedimentology and depositional environment of this important Fossil Lagerstätte are rather scarce. There are even fewer studies on the geochemistry and sedimentary diagenesis of the formation. A few exceptions include analyses of the organic matter composition (Baudin and Berthou, 1996; Neumann, 1999; Neumann et al., 2003) and a study of evaporite mineral pseudomorphism in the Nova Olinda Member (Martill et al., 2007). Some workers have examined spot samples from the Crato Formation in studies on the Araripe Group as a whole (e.g. Berthou et al., 1990) and a few assessments of the palaeoenvironment have been undertaken (Cavalcanti and Viana, 1990; Martill and Wilby, 1993). For a better understanding of the unusual taphonomy and exceptional preservation of the Crato fossils, a more detailed knowledge of the physico-chemical conditions of the aquatic palaeoenvironment is necessary. Because the Crato Formation is a heterolithic sequence with both clastic and carbonate deposition, it is clear that many different and often contrasting environments are represented by the sedimentary sequence. Many previous analyses fail to address the situation, preferring to summarize the unit as a whole, and providing generally unsatisfactory interpretations. Here we concentrate on the sedimentology and geochemistry of the Nova Olinda Member of the Crato Formation, with a view to elucidating the sedimentary and diagenetic environment that resulted in the exquisite preservation of the fossil assemblage.

Type: Chapter
Information: The Crato Fossil Beds of Brazil
Window into an Ancient World
, pp. 44 - 62

DOI: https://doi.org/10.1017/CBO9780511535512.005 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2007

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References

Baudin, F. and Berthou, P.-Y. 1996. Depositional environments of the organic matter of Aptian-Albian sediments from the Araripe Basin (NE Brazil). Bulletin Centres de Recherches, Exploration et Production, Elf-Aquitaine 20: 213–227.Google Scholar

Berthou, P.-Y., Viana, M. S. S. and Campos, D. de A. 1990. Coupe da la Formation Santana dans le secteur de “Pedra Branca” (Santana do Cariri) (Bassin d'Araripe, NE du Brésil). Contribution a l'étude de la sedimentologie et des paleoenvironments. In Campos, D. de A., Viana, M. S. S., Brito, P. M. and Beurlen, G. (eds), Atas do simpósio sobre a Bacia do Araripe e Bacias Interiores do Nordeste, Crato, 14-16 de Junho de 1990, Crato: 173–191.

Carvalho, I. S. 2000. Geological environments of dinosaur footprints in the intracratonic basins of northeast Brazil during the Early Cretaceous opening of the South Atlantic. Cretaceous Research 21: 255–267.CrossRef Google Scholar

Cavalcanti, V. M. M. and Viana, M. S. S. 1990. Faciologia dos sedimentos não-lacustres da formação Santana (Cretáceo Inferior da bacia do Araripe, Nordeste do Brasil). 1st Simpósio sobre a Bacia do Araripe e Bacias Interiores do Nordeste, Crato, 1990, Atas: 193–207.

Chumakov, N. M., Zharkov, M. A.Herman, A. B.et al. 1995. Climatic belts of the mid-Cretaceous time. Stratigraphy and Geological Correlation 3: 241–260.Google Scholar

Doyle, J. A., Jardiné, S. and Doerenkamp, A. 1982. Afropollis, a new genus of early angiosperm pollen, with notes on the Cretaceous palynostratigraphy and palaeoenvironments of northern Gondwana. Bulletin Centres de Recherches, Exploration et Production, Elf-Aquitaine 6: 39–117.Google Scholar

Glenn, C. R. and Kelts, K. 1991. Sedimentary rhythms in lake deposits, pp. 188–221. InEinsele, G.. and Seilacher, A. (eds), Cycles and Events in Stratigraphy. Berlin: Springer.Google Scholar

Kelts, K. and Hsü, K. J. 1978. Freshwater carbonate sedimentation, pp. 295–323. InLerman, A. (ed.), Lakes – Chemistry, Geology, Physics. Berlin: Springer.Google Scholar

Keupp, H. 1977. Der Solnhofener Plattenkalk – ein Blaugrünalgen Laminit. Palaeontologische Zeitschrift 51: 102–106.CrossRef Google Scholar

Martill, D. M. and Wilby. P. 1993. Stratigraphy, pp. 20–50. InMartill, D. M. (ed.), Fossils of the Santana and Crato Formations, Brazil. London: The Palaeontological Association.Google Scholar

Martill, D. M. and Wilby, P., Loveridge, R. F. and Heimhofer, U. 2007. Halite pseudomorphs in the Crato Formation (Early Cretaceous,?Late Aptian), Araripe Basin, northeast Brazil: further evidence for hypersalinity. Cretaceous Research (in press).CrossRef Google Scholar

Martínek, K., Blecha, M., Daněk, V.et al. 2006. Record of palaeoenvironmental changes in a Lower Permian organic-rich lacustrine succession: integrated sedimentological and geochemical study of the Rudník member, Krkonoše Piedmont Basin, Czech Republic. Palaeogeography, Palaeoclimatology, Palaeoecology 230: 85–128.CrossRef Google Scholar

Neumann, V. H. 1999. Estratigrafía, Sedimentología, Geoquímica y Diagénesis de los sistemas lacustres Aptiense – Albienses de la Cuenca de Araripe (NE Brazil). PhD Thesis Barcelona University.Google Scholar

Neumann, V. H., Borrego, A. G., Cabrera, L. and Dino, R. 2003. Organic matter composition and distribution through the Aptian-Albian lacustrine sequences of the Araripe Basin, northeastern Brazil. International Journal of Coal Geology 54: 21–40.CrossRef Google Scholar

Pancost, R. D., Crawford, N., Magness, S., Turner, A., Jenkyns, H. C. and Maxwell, J. R. 2004. Further evidence for the development of photic-zone euxinic conditions during Mesozoic oceanic anoxic events. Journal of the Geological Society, London 161: 353–364.CrossRef Google Scholar

Ponte, F. C. 1996. Arcabouço estrutural da Bacia do Araripe. Boletim do 4° Simpósio sobre o Cretáceo do Brasil, UNESP, Campus de Rio Claro, Sao Paulo: 169–177.

Sinninghe, Damsté J. S., Wakeham, S. G., Kohnen, M. E. L., Hayes, J. M. and Leeuw, J. W. 1993. A 6,000-year sedimentary molecular record of chemocline excursions in the Black Sea. Nature 362: 827–829.CrossRef Google Scholar

Stephenson, M. H., Leng, M. J., Michie, U. and Vane, C. H. 2006. Palaeolimnology of Palaeozoic lakes, focusing on a single lake cycle in the Middle Devonian of the Orcadian Basin, Scotland. Earth-Science Reviews 75: 177–197.CrossRef Google Scholar

Szulc, J. and Cwizewicz, M. 1989. The Lower Permian freshwater carbonates of the Slakow Graben, southern Poland: Sedimentary facies context and stable isotope study. Palaeogeography, Palaeoclimatology, Palaeoecology 70: 107–120.CrossRef Google Scholar

Tucker, M. E. and Wright, V. P. 1990. Carbonate Sedimentology. Oxford: Blackwell Scientific Publications.CrossRef Google Scholar

Zolitschka, B. 2003. Dating based on freshwater and marine laminated sediments, pp. 92–106. InMacKay, A., Battarbee, R., Birks, J. and Oldfield, F. (eds), Global change in the Holocene. London: Edward Arnold Publishers, London.Google Scholar