Aragonitic rostra of the Turonian belemnitid Goniacamax: arguments from diagenesis

• Autorzy: Dauphin Y , Williams C.T. , Barskov I.S.
• Języki publikacji: EN

Abstrakty

EN

The hypothesis that belemnitid rostra are formed by primary biogenic low−Mg calcite is widespread. However, the coexistence in the same rostrum of both aragonitic and calcitic components has been reported in true belemnites (Goniocamax, Turonian). A combined microstructural and chemical composition study of the comparison of shells with undisputed mineralogy from the same site as the Turonian Goniocamax, shows that these aragonitic shells display the effects of diagenetic alteration. These observations favour the hypothesis that belemnite rostra are composed of primary aragonite, rather than low−Mg calcite, and are consistent with all other cephalopod shells. Calcitic and aragonitic rostra are also known in other Dibranchiata such as Triassic Aulacocerida and Eocene Belopterina. Diagenetic changes such as shown here may clearly affect palaeo−environmental interpretations based on carbonate shells.

Słowa kluczowe

EN

Turonian; sea shell; Cephalopoda; belemnite; calcite; Goniocamax; rostrum; skeleton; sea cephalopod; diagenesis; paleoenvironment; freshwater shell; Belemnitida; aragonite; Siberia; belemnitid rostrum; Piasina River; paleontology

• Wydawca: -
• Czasopismo: Acta Palaeontologica Polonica
• Rocznik: 2007
• Tom: 52
• Numer: 1
• Opis fizyczny: p.85-97,fig.,ref.

Twórcy

autor

Dauphin Y

• Universite Paris XI-Orsay, F-91405 Orsay Cedex, France

autor

Williams C.T.

autor

Barskov I.S.

Bibliografia

• Bandel, K., Engeser, T., and Reitner, J. 1984. Die Embryonalentwicklung von Hibolites (Belemnitida, Cephalopoda). Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 167: 275–303.
• Barskov, I.S. Kiyashko, S.I., Dauphin, Y., and Denis, A. 1997. Microstructures des zones calcitiques et aragonitiques des rostres de Goniocamax (Belemnitida, Turonien, Sibérie du Nord). Geodiversitas 19: 669–680.
• Barskov, I.S. 1972. Microstructure of the skeletal layers of belemnites compared with external shell layers of other Mollusks. Paleontological Journal 4: 492–500.
• Barskov, I.S. 1973. Microstructure of the skeletal layers of Sepia and Spirula compared with the shell layers of other Mollusks. Paleontological Journal 3: 286–294.
• Bettencourt, V. and Guerra, A. 1999. Carbon− and oxygen isotope composition of the cuttlebone of Sepia officinalis: a tool for predicting ecological information? Marine Biology 133: 651–657.
• Boggild, O.B. 1930. The shell structure of the molluscs. Det Kongelige Danske Videnskabernes Selskabs Skrifter, Naturvidenskabelig og Mathematisk Afdeling 9: 231–326.
• Brand, U. 1986. Paleoenvironmental analysis of Middle Jurassic (Callovian) ammonoids from Poland: trace elements and stable isotopes. Journal of Paleontology 60: 293–301.
• Cochran, J.K., Rye, D.M., and Landman, N.H. 1981. Growth rate and habitat of Nautilus pompilius inferred from radioactive and stable isotope studies. Paleobiology 7: 469–480.
• Cuif, J.P., Dauphin, Y., Denis, A., Gaspard, D., and Keller, J.P. 1980. Continuité et périodicité du réseau organique intraprismatique dans le test de Pinna muricata Linné (Lamellibranche). Comptes Rendus hebdomadaires de l’Académie des Sciences de Paris (sér. D) 290: 759–762.
• Cuif, J.P., Dauphin, Y., and Lefèvre, R. 1977. Rapport de la localisation du strontium, magnésium et sodium avec la minéralogie et la microstructure de trois rostres d’Aulacocerida triasiques. Comptes Rendus hebdomadaires de l’Académie des Sciences de Paris (sér. D) 285: 1033–1036.
• Cuif, J.P., Denis, A., and Raguideau, A. 1983. Observations sur les modalités de mise en place de la couche prismatique du test de Pinna nobilis L. par l’étude des caractéristiques de la phase minérale. Haliotis 13: 131–141.
• Dauphin, Y. 1976. Microstructure des coquilles de Céphalopodes. I – Spirula spirula (L.) (Dibranchiata, Decapoda). Bulletin du Museum National d’Histoire Naturelle de Paris (3èm sér.) 382, Sciences de la Terre 54: 197–238.
• Dauphin, Y. 1981. Microstructures des coquilles de Céphalopodes. II – La seiche (Dibranchiata, Decapoda). Palaeontographica A 176: 35–51.
• Dauphin, Y. 1983. Microstructure du phragmocône du genre triasique Aulacoceras (Cephalopoda – Coleoidea) – remarques sur les homologies des tissus coquilliers chez les Céphalopodes. Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 165: 418–437.
• Dauphin, Y. 1986. Microstructure des coquilles de Céphalopodes: la partie apicale de Belopterina (Coleoidea). Bulletin du Museum National d’Histoire Naturelle de Paris (3èm sér.) 8, C1: 53–75.
• Dauphin, Y. 1987. Les microstructures des rostres de Céphalopodes. VIII – apport de la microanalyse localisée pour l’interprétation de l’état diagénétique des rostres d’Aulacocéridés (Trias – Turquie). Palaeontographica A 199: 217–231.
• Dauphin, Y. 1988. Diagenèse aragonite–calcite chez les Céphalopodes coléoïdes: exemples des rostres d’Aulacoceras (Trias de Turquie) et de Belopterina (Eocène de France). Bulletin du Museum National d’Histoire Naturelle de Paris (4èm sér.) 10, C2: 107–135.
• Dauphin, Y. 2001a. Caractéristiques de la phase organique soluble des tests aragonitiques des trois genres de céphalopodes actuels.Neues Jahrbuch für Geologie und Paläontologie, Monatshefte 2: 103–123.
• Dauphin, Y. 2001b. Comparative studies of skeletal soluble matrices from some Scleractinian corals and Molluscs. International Journal of Biological Macromolecules 28: 293–304.
• Dauphin, Y. and Cuif, J.P. 1980. Implications systématiques de l’analyse microstructurale des rostres de trois genres d’Aulacocéridés triasiques (Cephalopoda – Coleoidea). Palaeontographica A 169: 28–50.
• Dauphin, Y., Cuif, J.P., Doucet, J., Salomé, M., Susini, J., and Williams, C.T. 2003a. In situ chemical speciation of sulfur in calcitic biominerals and the simple prism concept. Journal of Structural Biology 142: 272–280.
• Dauphin, Y., Cuif, J.P., Doucet, J., Salomé, M., Susini, J., and Williams, C.T. 2003b. In situ mapping of growth lines in the calcitic prismatic layers of mollusc shells using X−ray absorption near−edge structure (XANES) spectroscopy at the sulphur edge. Marine Biology 142: 299–304.
• Engeser, T. and Reitner, J. 1983. Chitinobelus acifer Fischer 1981, ein Belemnoteuthide (Coleoidea) mit Epirostrum. Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 165: 496–501.
• Grégoire, C. 1969. Further studies on structure of the organic components in mother−of−pearl, especially in Pelecypods. Bulletin de l’Institut Royal de Sciences naturelles de Belgique 36: 1–22.
• Grégoire. C., Duchateau, G., and Florkin, M. 1955. La trame protidique des nacres et des perles. Annales de l’Institut Océanographique 31: 1–36.
• Hendry, J.P., Ditchfield, P.W., and Marshall, J.D. 1995. Two−stage neomorphism of Jurassic aragonitic bivalves: implications for early diagenesis. Journal of Sedimentary Research A 65: 214–224.
• Jeletzky, J.A. 1966. Comparative morphology, phylogeny and classification of fossil Coleoidea. University of Kansas Paleontological Contributions, Mollusca 7: 1–162.
• Jiménez−Berrocoso A., Zuluaga M.C., and Elorza, J. 2004. Minor− and trace−element intra−shell variations in Santonian inoceramids (Basque-Cantabrian Basin, northern Spain): diagenetic and primary causes. Facies 50: 35–60.
• Kostak, M., Cech, S., Ekrt, B., Mazuch, M., Wiese, F., Voigt, S., and Wood, C.J. 2004. Belemnites of the Bohemian Cretaceous Basin in a global context. Acta Geologica Polonica 54: 511–533.
• Lowenstam, H.A. and Weiner, S. 1989. On Biomineralization. 324 pp. Oxford University Press, Oxford.
• Makowski, H. 1962. La faune callovienne de Lukow en Pologne. Palaeontologia Polonica 4: 1–64.
• Muller−Stoll, H. 1936. Beitrage zur Anatomie der Belemnoidea. Nova Acta Leopoldina (NS) 4: 159–226.
• Mutvei, H. 1964. On the shells of Nautilus and Spirula with notes on the shell secretion in non cephalopod molluscs. Arkiv för Zoologi 16: 221–278.
• Naydin, D.P. [Najdin, D.P.], Barskov, I.S., and Kiyachko, S.I. [Kijačko, S.I] 1987. Aragonitic and calcitic composition of the belemnitid rostra from the Upper Cretaceous of the western Taymyr: stable isotopic composition of oxygen and carbon [in Russian]. Paleontologičeskij žurnal 3: 3–8.
• Oba, T., Kai, M., and Tanabe, K. 1992. Early life history and habitat of Nautilus pompilius inferred from oxygen isotope examinations. Marine Biology 113: 211–217.
• Putten, E.V., DeHairs, F., Keppens, E., and Baeyens, W. 2000. High resolution distribution of trace elements in the calcite shell layer of modern Mytilus edulis: environmental and biological controls. Geochimica et Cosmochmica Acta 64: 997–1011.
• Reitner, J. and Engeser, T. 1982. Phylogenetic trends in phragmocone−bearing coleoids (Belemnomorpha). Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 164: 156–162.
• Spaeth, C. 1971. Aragonitische und calcitische Primarstrukturen im Schalenbau eines belemniten aus der englischen Unterkreide. Paläont. Zeitschrift 45: 33–40.
• Taylor, J.D., Kennedy, W.J., and Hall, A. 1969. The shell structure and mineralogy of the Bivalvia. Introduction. Nuculacae—Trigonacae. Bulletin of the British Museum of Natural History, Zoology 3: 1–125.
• Teys, R.V., Kiseleskiy, M.A., and Naydin, D.P. 1978. Oxygen and carbon isotopic composition of organogenic carbonates and concretions in the Late Cretaceous rocks of Northwestern Siberia. Geochemistry International 15: 74–81.