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Biostratigraphy and evolution of Late Carboniferous and Early Permian smaller foraminifers from the Barents Sea (offshore Arctic Norway)

Published online by Cambridge University Press:  20 May 2016

John R. Groves  and
Gregory P. Wahlman
John R. Groves
Affiliation:
Amoco Exploration and Production Technology Group, P. O. Box 3092, Houston, Texas 77253
Gregory P. Wahlman
Affiliation:
Amoco Exploration and Production Technology Group, P. O. Box 3092, Houston, Texas 77253
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Abstract

Nearly continuous cores from a 500-meter interval of upper Moscovian through post-Artinskian carbonate strata on the Finnmark Platform have yielded rich assemblages of fusulinaceans and smaller foraminifers. The fusulinaceans provide an independent time framework for evaluating stratigraphic occurrences of associated smaller foraminifers. Information derived from this study has been integrated with that from previous investigations to produce a smaller foraminiferal biostratigraphic model for the High Arctic. Kasimovian strata are characterized by occurrences of Nodosinelloides spp., Protonodosaria spp. and Hemigordius schlumbergeri. Overlying lower Gzhelian beds are identified by the appearances of Raphconilia modificata and Amphoratheca iniqua. Tezaquina clivuli and Cribrogenerina gigas first occur in upper Gzhelian strata, and Asselian rocks contain appearances of Geinitzina postcarbonica and Pachyphloia spp. Phylogenetic reconstructions suggest that the Late Carboniferous-Early Permian pseudovidalinids (Archaediscacea) derived from the Pseudoammidiscidae, as did the older group of predominantly Early Carboniferous archaediscaceans. The repeated development of similar morphologies within the two groups of archaediscaceans includes examples of both convergence and iterative evolution. The Protonodosariidae and Syzraniidae most likely evolved from an earlandiid ancestor. The syzraniids gave rise to the Geinitzinidae, which in turn gave rise to the Pachyphloiidae. As in the archaediscaceans, evolution within and among the Earlandiidae, Protonodosariidae, Syzraniidae, Geinitzinidae and Pachyphloiidae includes multiple examples of repeated patterns. Two key phenotypic developments seemingly led to bursts of diversification in different groups throughout late Paleozoic foraminiferal evolution. The acquisition of an outer hyaline or pseudofibrous wall layer was a morphologic breakthrough followed by taxonomic radiation in both groups of archaediscaceans and in the Earlandia-Syzrania lineage. The second major event was the shift from an undivided tubular morphology to uniserial morphology in both the Earlandiidae-Protonodosariidae and Syzraniidae-Geinitzinidae lines. Nodosinelloides pinardae is proposed as a new name for Nodosaria grandis Lipina, 1949 (preoccupied).

Type
Research Article
Information
Journal of Paleontology , Volume 71 , Issue 5 , September 1997 , pp. 758 - 779
Copyright
Copyright © The Paleontological Society 

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References

Altiner, D. 1988. Pseudovidalinidae n. fam. and Angelina n. gen. from the Upper Permian of south and southeast Turkey. Revue de Paléobiologie, Special Volume No. 2 (Benthos '86):2536.Google Scholar
Bogush, O. I., and Yuferev, O. V. 1966. Carboniferous and Permian foraminifers from Verkhoyania. Akademiya Nauk SSSR, Sibirskoye Otdelenie, Institut Geologii I Geofiziki, Izdatel'stvo “Nauka”, Moskva, 208 p. (in Russian)Google Scholar
Bozorgnia, F. 1973. Paleozoic foraminiferal biostratigraphy of central and east Alborz Mountains, Iran. National Iranian Oil Company Geological Laboratories Publication, 4, 185 p.Google Scholar
Brady, H. B. 1876. Carboniferous and Permian foraminifera (the genus Fusulina excepted). Palaeontological Society Monographs, 30, 166 p.Google Scholar
Brazhnikova, N. E., Vakartchuk, G. I., Vdovenko, M. V., Niniitchenko, L. V., Karpova, M. A., Kolomietz, La. I., Potievskaya, P. D., Rostovtseva, L. P., and Chevtchenko, G. D. 1967. Marker microfaunal horizons of the Carboniferous and Permian of the Dniepr-Donetz Basin. Akademiya Nauk Ukrainskoi SSR, Institut Geologicheskii Nauk, Trudy, 224 p. (in Russian)Google Scholar
Brenckle, P. L., Ramsbottom, W. H. C., and Marchant, T. R. 1987. Taxonomy and classification of Carboniferous archaediscacean foraminifers. Courier Forschungsinstitut Senckenberg, 98:1124.Google Scholar
Brenckle, P. L., and Wahlman, G. P. 1994. Conilia, a new Upper Paleozoic pseudovidalinid foraminifer. Mémoires Institut Géologique de l'Université Catholique de Louvain, 35:169176.Google Scholar
Brenckle, P. L., and Wahlman, G. P. 1996. Raphconilia, a new name for the Upper Paleozoic pseudovidalinid foraminifer Conilia Brenckle and Wahlman, 1994. Journal of Foraminiferal Research, 26:184.CrossRefGoogle Scholar
Bugge, T., Mangerud, G., Elvebakk, G., Mørk, A., Nilsson, I., Fanavoll, S., and Os Vigran, J. 1995. The Upper Paleozoic succession on the Finnmark Platform, Barents Sea. Norsk Geologisk Tidsskrift, 75:330.Google Scholar
Cherdyntsev, W. 1914. Foraminiferal fauna of the Permian deposits of the eastern belt of European Russia. Kazan, Trudy Obshchestva Estestvoispytateley pri Imperatorskomy Kazanskomy Universitety, 46:388. (in Russian)Google Scholar
Cifelli, R. 1969. Radiation of Cenozoic planktonic foraminifera. Systematic Zoology, 18:154168.CrossRefGoogle Scholar
Cummings, R. H. 1955. Nodosinella Brady, 1876, and associated Upper Palaeozoic genera. Micropaleontology, 1:221238.CrossRefGoogle Scholar
Cushman, J. A. 1928. Foraminifers, their classification and economic use. Cushman Laboratory for Foraminiferal Research, Special Publication 1, 401 p.Google Scholar
Cushman, J. A. and Waters, J. A. 1928a. Upper Paleozoic foraminifera from Sutton County, Texas. Journal of Paleontology, 2:358371.Google Scholar
Cushman, J. A. and Waters, J. A. 1928b. The development of Climacammina and its allies in the Pennsylvanian of Texas. Journal of Paleontology, 2:119130.Google Scholar
Cutbill, J. L., and Challinor, A. 1965. Revision of the stratigraphical scheme for the Carboniferous and Permian rocks of Spitsbergen and Bjørnøya. Geological Magazine, 102:418439.CrossRefGoogle Scholar
Davydov, V. I. 1986. Discovery of Nodosaria in Upper Carboniferous deposits of Darvaz. Doklady Akademii Nauk SSSR, 290:913916. (in Russian)Google Scholar
Davydov, V. I. 1988. Archaediscidae in the Upper Carboniferous and Lower Permian. Revue de Paléobiologie, Special Volume No. 2 (Benthos '86):3946.Google Scholar
Davydov, V. I. 1991. Late Carboniferous and Permian archaediscids (foraminifera): homeomorphy or bradytely? Bulletin Moskovskoye Obshchestva Ispytatelei Prirody, Otdelenie Geologii, 66:5058. (in Russian with English abstract)Google Scholar
Ehrenberg, C. G. 1854. Mikrogeologie. L. Voss, Leipzig, 374 p.Google Scholar
von Eichwald, C. E. 1830. Zoologia specialis. Vilnae: C. E. Eichwaldus, 2, 323 p.Google Scholar
Forbes, C. L., Harland, W. B., and Hughes, N. F. 1958. Paleontological evidence for the age of the Carboniferous and Permian rocks of Spitsbergen. Geological Magazine, 95:465490.Google Scholar
Franke, A. 1936. Die Foraminiferen des deutschen Lias. Preussische Geologische Landesanstalt, Abhandlungen, 169, 138 p.Google Scholar
Galloway, J. J. 1933. A Manual of Foraminifera. Principia Press, Inc., Bloomington, Indiana, 483 p.Google Scholar
Gerke, A. A. 1952. Microfauna from Permian deposits of the Nordvik District and their stratigraphic indications. Nauchno-issledovatel'skii Institut Geologii Arktiki (Leningrad), Trudy, v. 28. (in Russian)Google Scholar
Gerke, A. A. 1959. On a new genus of Permian nodosariid foraminifera and the limiting characteristics of the genus Nodosaria. Nauchno-issledovatel'skii Institut Geologii Arktiki (Leningrad), Trudy, vypusk 17:4159. (in Russian)Google Scholar
Golonka, J., Ross, M. I., and Scotese, C. R. 1994. Phanerozoic paleogeographic and paleoclimatic modeling maps, p. 147. In Embry, A. F., Beauchamp, B., and Glass, D. J. (eds.), Pangea: Global environments and resources. Canadian Society of Petroleum Geologists Memoir, 17.Google Scholar
Groves, J. R. 1992. Stratigraphic distribution of non-fusulinacean foraminifers in the Marble Falls Limestone (Lower-Middle Pennsylvanian), western Llano region, central Texas, p. 145162. In Sutherland, P. K. and Manger, W. L. (eds.), Recent advances in Middle Carboniferous biostratigraphy - a symposium. Oklahoma Geological Survey Circular, 94.Google Scholar
Groves, J. R., Nassichuk, W. W., Lin, Rui and Pinard, S. 1994. Middle Carboniferous fusulinacean biostratigraphy, northern Ellesmere Island (Sverdrup Basin, Canadian Arctic Archipelago). Geological Survey of Canada Bulletin, 469, 55 p.Google Scholar
Hallam, A., ed. 1977. Patterns of evolution, as illustrated by the fossil record. Developments in Palaeontology and Stratigraphy, 5. Elsevier, Amsterdam-Oxford-New York, 591 p.Google Scholar
Henderson, C. M., Pinard, S., and Beauchamp, B. 1995. Biostratigraphic and sequence stratigraphic relationships of Upper Carboniferous conodont and foraminifer distribution, Canadian Arctic Archipelago. Bulletin of Canadian Petroleum Geology, 43:226246.Google Scholar
Hobson, J. P. Jr., Caldwell, C. D., and Toomey, D. F. 1985. Sedimentary facies and biota of Early Permian deep-water allochthonous limestone, southwest Reagan County, Texas, p. 93139. In Crevello, P. D. and Harris, P. M. (eds.), Deep-water carbonates: buildups, turbidites, debris flows and chalks - a core workshop. Society of Economic Paleontologists and Mineralogists Core Workshop, New Orleans, March 23-24, 1985, Volume 6.Google Scholar
Howchin, W. 1895. Carboniferous foraminifera of Western Australia, with descriptions of new species. Transactions and Proceedings of the Royal Society of South Australia, 19:194198.Google Scholar
International Commission on Zoological Nomenclature. 1985. International Code of Zoological Nomenclature. University of California Press, Berkeley and Los Angeles, 338 p. (in French and English)Google Scholar
Jenny-Deshusses, C. 1985. Rectostipulina, n. gen. (= Stipulina Lys 1978), un organisme incertae sedis du Permien supérieur de la Téthys moyen-orientale: description morphologique et remarques stratigraphiques. Revue de Paléobiologie, 4:153158.Google Scholar
King, W. 1850. Permian fossils of England. Palaeontological Society Monographs, 3, 250 p.Google Scholar
Kireeva, G. D. 1958. On the age of the Copper Sandstone Formation of the Donbas and the foraminifera occurring in it. Vsesoyuznogo Neftianogo Nauchno-Issledovatelskogo Geologo-Razvedochnogo Institut (VNIGRI), Paleontologicheskogo Sbornik, Trudy, vypusk 9:157176. (in Russian)Google Scholar
Konovalova, M. V. 1962. New species of Sakmarian foraminifers from the Timan-Pechora province. Akademiya Nauk SSSR, Paleontologicheskii Zhurnal, 3:1623. (in Russian)Google Scholar
Konovalova, M. V. 1991. Stratigraphy and fusulinids from the Upper Carboniferous and Lower Permian of the Timan-Pechora oil- and gas-bearing province. Ministerstvo Geologii SSSR, Ukhtinskaya Geologorazvedochnaya Ekspeditsiya, Moskva “Nedra”, 201 p. (in Russian)Google Scholar
Lamarck, J. B. 1812. Extrait du cours de Zoologie du Muséum d'Histoire Naturella sur les animaux invertèbres. d'Hautel, Paris, 127 p.Google Scholar
Lange, E. 1925. Eine Mittelpermische Fauna von Guguk Bulat (Padanger Oberland, Sumatra). Verhandelingen van het Geologisch-Mijnbouwkundig Genootschap voor Nederland en Koloniën, Geologische serie 7:213295.Google Scholar
Likharev, B. K. 1939. Atlas of guide fossils of the USSR, VI: Permian System. Tsentralnyi Nauchno-Issledovalet'skii Geologo-Razvedochnii Institut SSSR, 269 p. (in Russian)Google Scholar
Lipina, O. A. 1949. Smaller foraminifers from the buried massifs of Bashkiria. Akademiya Nauk SSSR, Trudy Instituta Geologicheskikh Nauk, vypusk 105, Geologicheskaya Seriya 35:198235. (in Russian)Google Scholar
Lipina, O. A. 1950. Foraminifers from the Upper Devonian of the Russian Platfrom. Trudy Instituta Geologicheskikh Nauk, Akademiya Nauk SSSR, 119:110133. (in Russian)Google Scholar
Loeblich, A. R. Jr., and Tappan, H. 1964. Sarcodina, chiefly “thecamoebians” and Foraminiferida, Part C. In Moore, R. C. (ed.), Treatise on Invertebrate Paleontology, Protista 2. Geological Society of America and University of Kansas Press. 2, 900 p.Google Scholar
Loeblich, A. R. Jr., and Tappan, H. 1984. Suprageneric classification of the Foraminiferida (Protozoa). Micropaleontology, 30:170.Google Scholar
Loeblich, A. R. Jr., and Tappan, H. 1988. Foraminiferal genera and their classification. Van Nostrand Reinhold Company, New York, 2, 970 p.Google Scholar
Loriga, C. 1960. Foraminiferi del Permiano superiore delle Dolomiti (Val Gardena, Val Badia, Val Marebbe). Bollettino della Società Paleontologica Italiana, 1:3373.Google Scholar
Lys, M., Stampfli, G., and Jenny, J. 1978. Biostratigraphie du Carbonifère et du Permien de l'Elbourz oriental (Iran du NE). Note du Laboratorie de Paléontologie de l'Université de Genève, 10:6378.Google Scholar
Mamet, B. L., and Pinard, S. 1992. Note sur la taxonomie des petits foraminifères du Paléozoique supérieur. Bulletin de la Société belge de Géologie, 99:373397.Google Scholar
Miklukho-Maklay, K. V. 1954. Foraminifers from Upper Permian deposits of the northern Caucasus. Trudy Vsesoyuznogo Nauchno-Issledovatel'skogo Geologicheskogo Instituta (VSEGEI), Gosgeoltekhizdat, p. 1162. (in Russian)Google Scholar
Nakrem, H. A., Nilsson, I., and Mangerud, G. 1992. Permian biostratigraphy of Svalbard (Arctic Norway) - a review. International Geology Review, 34:933959.Google Scholar
Neugeboren, J. L. 1852. Foraminiferen von Ober-Lapugy; vierter Artikel (Schluss). Vereins Naturwissenschaftlicher Hermannstadt, Verhandlungen, Mitteilungen, Jahrgang 3, 4:5059.Google Scholar
Nilsson, I. 1993. Upper Paleozoic fusulinid stratigraphy of the Barents shelf and surrounding areas. Unpublished , University of Tromsø, Tromsø, Norway.Google Scholar
Nilsson, I. 1994. Upper Paleozoic fusulinid assemblages, Wandel Sea Basin, north Greenland. Rapport Grønlands geologiske Undersøgelse, 161:4571.Google Scholar
Nilsson, I. and Davydov, V. I. 1992. Upper Carboniferous (Kasimovian-Gzhelian) and Lower Permian (Asselian-Sakmarian) fusulinid stratigraphy in central Spitsbergen, Arctic Norway. IKU Petroleumsforskning a.s., Report No. 23.1356.00/07/92, 185 p.Google Scholar
Okimura, Y., and Ishii, K.-I. 1981. Upper Permian and Lower Triassic foraminifera from Guryul Ravine and the spur three kilometers north of Barus, p. 2538. In Nakazawa, K. and Kapoor, H. M. (eds.), The Upper Permian and Lower Triassic faunas of Kashmir. Palaeontologica Indica, Memoirs of the Geological Survey of India, N.S., v. 46.Google Scholar
OrbignyA. D., d'. A. D., d'. 1826. Tableau méthodique de la classe des Céphalopodes. Annales des Sciences Naturelles, 7:245314.Google Scholar
OrbignyA. D., d'. A. D., d'. 1840. Mémoire sur les Foraminifères de la craie blanche du bassin de Paris. Société Géologique de France, Mémoires, 4:151.Google Scholar
Orlov, Yu. A. (ed.). 1959. Fundamentals of Paleontology (reference book for Soviet paleontologists and geologists). Izdatel'stvo Akademii Nauk SSSR, Moskva, 482 p. (in Russian)Google Scholar
Pinard, S. 1989. Taxonomie des petits foraminifères du Carbonifère-Permien inférieur du bassin de Sverdrup, Arctique canadien. Unpublished , Université de Montréal, 3, 782 p.Google Scholar
Plummer, H. J. 1930. Calcareous foraminifera in the Brownport Shale near Bridgeport, Texas. University of Texas Bulletin, 3019:121.Google Scholar
Potievskaya, P. D. 1962. Representatives of some families of smaller foraminifers from the Lower Permian of the northwestern region of the Donbass. Akademiya Nauk Ukrainskoi SSR, Trudy Instituta Geologicheskikh Nauk, Seriya Stratigrafii i Paleontologii, vypusk 44:4994. (in Russian)Google Scholar
Pronina, G. P., and Gubenko, T. A. 1990. Planoarkhedistidy pozdney permi zakavkaz'ya (Planoarchaediscids from the Late Permian of Transcaucasia). Paleontologicheskii Zhurnal, 24(2):119123.Google Scholar
Rauser-Chernousova, D. M. 1949. On the ontogenesis of some Paleozoic foraminifers. Akademiya Nauk SSSR, Trudy Paleontologicheskogo Institut, 20:339353. (in Russian)Google Scholar
Rauser-Chernousova, D. M., and Fursenko, A. V. 1937. Determination of foraminifers from the oil-producing regions of the USSR. Glavnaya Redaktsya Gorno-Toplivnoi Literatury Leningrad, Moskva, 315 p. (in Russian)Google Scholar
Reitlinger, E. A. 1950. Foraminifera from the Middle Carboniferous deposits of the central part of the Russian Platform (exclusive of the family Fusulinidae). Akademiya Nauk SSSR, Institut Geologicheskii Nauk, Trudy, vypusk 126, Geologicheskii Serii No. 47:1127. (in Russian)Google Scholar
Reitlinger, E. A. 1971. Some problems of systematics in the light of evolutionary stages of Upper Paleozoic foraminifers. Akademiya Nauk SSSR Voprosy Mikropaleontologii, 14:316. (in Russian with English summary)Google Scholar
Reuss, A. E. 1866. Die Foraminiferen und Ostrakoden der Kreide am Kanara-See bei Küstendsche. Königliche Akademie der Wissenschaften zu Wien, Mathematische-Naturwissenschaften Classe, Sitzungsberichte, 52:445470.Google Scholar
Ross, C. A. 1965. Fusulinids from the Cyathophyllum limestone, central Vestspitsbergen. Contributions to the Cushman Foundation for Foraminiferal Research, 16:7486.Google Scholar
Ross, C. A., and Ross, J. R. P. 1985. Carboniferous and Permian biogeography. Geology, 13:2730.Google Scholar
Schubert, R. J. 1915. Die Foraminiferen des jüngeren Paläozoikums von Timor, p. 4759. In Wanner, J. (ed.), Paläontologie von Timor. Stuttgart, E. Schweizerbart, Leif. 2.Google Scholar
Sellier de Civrieux, J. M., and Dessauvagie, T. F. J. 1965. Reclassification de quelques Nodosariidae, particulièrement du Permien au Lias. Publications de l'Institut d'études et de recherches minières de Turquie, 124, 178 p.Google Scholar
Sosipatrova, G. P. 1967. Upper Paleozoic foraminifera of Spitsbergen. In Sokolov, V. N. (ed.), Stratigraphy of Spitsbergen. Institut Geologii Arktiki, Leningrad, 238 p. (in Russian, English translation available from the Lending Division of the British Library Board, 1977, p. 125-163)Google Scholar
Sosipatrova, G. P. 1969. Foraminifers from the Starostinskoi Suite of Spitsbergen. Nauchno-issledovatel'skii Institut Geologi Arktiki, Ministerstva Geologii SSSR, Uchenie Zapiski Paleontologiya i Biostratigrafiya, 26:4679. (in Russian)Google Scholar
Spandel, E. 1898. Die Foraminiferen des deutschen Zechsteins (vorläufige Mitteilung) und ein zweifelhaftes mikroskopisches Fossil ebendaher. Nürnberg, Verlag des Verlags-Instituts “General-Anzeiger,” 15 p.Google Scholar
Spandel, E. 1901. Die Foraminiferen des Permo-Carbon von Hooser, Kansas, Nord Amerika. Festschrift, Saecular-Feier der Naturhistorischen Gesellschaft in Nürnberg, 1801-1901, p. 177194.Google Scholar
Suliemanov, I. S. 1949. Some smaller foraminifers from Upper Paleozoic deposits of Bashkiria. Akademiya Nauk SSSR, Trudy Instituta Geologicheskikh Nayk, vypusk 105, Geologicheskaya, 35:236244. (in Russian)Google Scholar
Vachard, D., and Montenat, C. 1981. Biostratigraphie, micropaléontologie et paléogéographie du Permien de la région de Tezak (Montagnes Centrales d'Afganistan). Palaeontolographica, Abteilung B, 178:188.Google Scholar
Verville, G. J., Sanderson, G. A., Brenckle, P. L., and Lane, H. R. 1973. Upper Paleozoic biozonation in the Unit No. 19 well, Church Buttes Field, Uinta County, Wyoming. Twenty-fifth Field Conference—1973, Wyoming Geological Association Guidebook, p. 165171.Google Scholar
Waagen, W., and Wentzel, J. 1886. Salt Range fossils. Palaeontologica Indica, Series 13, 1:854966.Google Scholar
Wahlman, G. P., Davydov, V. I., and Nilsson, I. 1995. Fusulinid biostratigraphy of subsurface cores from the Conoco 7128/6-1 well, offshore Barents Sea, Arctic Norway. XIII International Congress on Carboniferous-Permian (XIII ICC-P), Abstracts, Panstwowy Instytut Geologiczny, Krakow, p. 150.Google Scholar
Wisniowski, T. 1890. Mikrofauna ilow ornatowych okolicy Krakowa: Czesc I – Otwornice gornego Kellowayu w Grojcu. Akademia Umiejetnosci Krakowie, Wydzialu Matematyczno-Przyrodniczego, Pamietnik, Krakow, 17:194.Google Scholar
Worsley, D., Aga, O. J., Dalland, A., Elverhøi, A., and Thon, A. 1986. The geological history of Svalbard – evolution of an Arctic archipelago. Den norske stats oljeselskap, Stavanger, 121 p.Google Scholar
WorsleyD., O. D., O., Agdestein, T., Gjelberg, J., and Steel, R. J. 1990. Late Paleozoic basinal evolution of Bjørnøya: Implications for the Barents Sea. Geonytt 1:124125.Google Scholar
WorsleyD., O. D., O., and Edwards, M. B. 1976. The Upper Paleozoic succession of Bjørnøya. Norsk Polarinstitutt Årbok, 1974, p. 1734.Google Scholar
Zolotova, V. P., and Baryshnikov, V. V. 1980. Foraminifers from the stratotype area of the Kungurian Stage. Akademiya Nauk SSSR, Ural'skii Nauchnyi Tsentr, “Biostratigrafiya Artinskskogo i Kungurskogo Yarusov Urala,” p. 72105. (in Russian)Google Scholar