Evolution of Habitat Depth in the Jurassic– Cretaceous Ammonoids

Total Page:16

File Type:pdf, Size:1020Kb

Evolution of Habitat Depth in the Jurassic– Cretaceous Ammonoids COMMENTARY COMMENTARY Evolution of habitat depth in the Jurassic– Cretaceous ammonoids Kazuyoshi Moriya1 oxygen isotopic analyses of shell materials of Department of Earth Sciences, Faculty of Education and Integrated Arts and Sciences, ammonoids reveal the temperature at which Waseda University, Shinjuku-ku, Tokyo 169-8050, Japan the shell was secreted. This technique, called oxygen isotopic thermometry, has been widely Ammonoids, a group of cephalopods with body fossils and close modern relatives. For used in paleoclimatological and paleobiologi- external chambered shells, arose in the early example, although one may usually imagine that cal research. It was also applied to ammonoid Devonian and went extinct at the Cretaceous/ ammonoids were planktic or nektic organisms fossils more than 40 y ago (2, 3). Many scien- Paleogene (K/Pg) boundary. During their 340- within a water column, like the Nautilus,which tists, however, assumed that ammonoids were planktic or nektic organisms, so their discus- million-y history, ammonoids suffered three is the sole surviving cephalopod bearing an sion focused mainly on growth rates inferred major diversity crises at the end of the Devonian, external chambered shell, there is very little by identifying sinusoidal patterns, hence sea- Permian, and Triassic Periods, and the terminal direct evidence showing the habitat depth of sonality, in the temperature data. Among extinction event at the K/Pg boundary. Because ammonoids within an ancient water column. those previous workers, Anderson et al. (4) of their rapid morphological evolution and rich Sessa et al. (1) shed new light on the habitat analyzed oxygen isotopic composition of the fossil record, ammonoids have been used to depth of the Cretaceous ammonoids using geo- middle Jurassic ammonoids and compared determine the relative age of marine strata and chemical proxy records. When calcium carbon- the results with those of co-occurring benthic correlation since the dawn of stratigraphy. ate, which composes the shell material of many and planktic organisms. The isotopic tempera- Although the morphological analyses of shell marine invertebrates, is secreted within the tures of Kosmoceras (Stephanoceratoidea) were materials have provided some insights into ocean,thestableoxygenisotopiccomposition significantly warmer than those of benthic ontogeny and evolution, their biological nature of the carbonate is predominantly determined bivalves and slightly cooler than those of sur- is poorly understood because of the lack of soft by the ambient ocean temperature. Therefore, face-dwelling organisms, indicating a planktic or nektic mode of life of Kosmoceras (i.e., a position high in the water column) (Fig. 1). Phylogeny and evolution of mode of life In contrast, when Moriya et al. (5) analyzed Ma Stage of the Jurassic–Cretaceous ammonoids isotopic temperatures of the late Cretaceous Period ammonoids and co-occurring planktic and ben- 70 Maastrichtian (1) (1) thic organisms, isotopic temperatures of all 75 Campanian ratoidea e ammonoids analyzed, regardless of their taxo- (5) (5) (5) Hoplitoidea (5) Santonian Turrilitoidea hoc nomic and morphological relationships, were Coniacian nt dea a c oi essentially identical to those of benthic fora- Turonian t i A Acanthoceratoidea Cenomanian minifers and bivalves, and significantly cooler 100 aph (8) c (8) S Scaphitoidea a than those of planktic foraminifers, indicating Albian dea i sitoidea a demersal (bottom dwelling) habitat of these e nctoide ammonoid species (Fig. 1). Because paleontol- hi gonito Cretaceous Aptian shay a r sp e a ogists working on ammonoids expected that 125 D Deshayesitoidea eri Desmoceratoidea Douvilleiceratoidea Tet Tetragonitoidea ide Barremian P Perisphinctoidea the morphological features of the external Hauterivian ato (9) r e shells must, at least partly, represent their ecol- Valanginian d toidea o a Berriasian yl ogy, these results raised many arguments c a n de Tithonian A Ancyloderatoidea 150 idea on ammonoid ecology. Since the works of Kimmeridgian hanocer ato Anderson et al. (4) and Moriya et al. (5), the use Oxfordian er c Step Stephanoceratoidea Callovian o l (6) of isotopic thermometry on ammonoid fossils Bathonian Spiroceratoi Spiroceratoidea (4) Bajocian Hap Haploceratoidea for identifying their ecology has becomes more 175 Aalenian widespread (6–8) (Fig. 1). However, because of Toarcian technical difficulties in identifying thermal Jurassic Planktic or nektic Pliensbachian Hildoceratoidea structure of the water column with analyzing Sinemurian Demersal Eoderoceratoidea apparent planktic and benthic organisms, a full Lytoceratoidea Phylloceratoidea Psiloceratoidea (Bottom dwelling) Hettangian set of data for planktic and benthic organisms Fig. 1. Phylogeny and evolution of mode of life of the Jurassic–Cretaceous ammonoids. Age of each stage boundary is from Gradstein et al. (16). Phylogeny of ammonoids is cited from Yacobucci (17). Open white circles represent Author contributions: K.M. wrote the paper. isotopic results indicating demersal (bottom dwelling) habitat at the age plotted on each lineage. Gray filled circles The author declares no conflict of interest. indicate planktic or nektic habitat. Numbers at left bottom of each circle represent references for each data. Pink bar, Phylloceratina (5); orange bar, Lytoceratina (5); yellow bar, Ammonitina; pale green bar, Haploceratina; pale blue, See companion article 10.1073/pnas.1507554112. Perisphinctina (4–6, 8, 9); purple bar, Ancyloceratina (1, 5, 8). 1Email: [email protected]. www.pnas.org/cgi/doi/10.1073/pnas.1520961112 PNAS Early Edition | 1of2 Downloaded by guest on October 4, 2021 co-occurring with ammonoids have rarely been tion, and other ecological factors must K/Pg terminal extinction event. Alternatively, described since Moriya et al. (5). An additional have been critical for ammonoids at the habitat of hatchling and juvenile ammonoids unanswered question is how habitat depth pref- K/Pg boundary. One potential hypothesis is the other candidate for the fatal ecology for erences evolved in ammonoids, especially in the is the food habit. Kruta et al. (10) presented the latest Cretaceous ammonoids. On the latest Cretaceous time just before the terminal that the late Cretaceous baculites preyed basis of their small embryonic shell size (0.5– extinction event. For discussing mechanisms upon planktic microorganisms. Because it is 1.8 mm in diameter) and the occurrence of and dynamics of paleobiodiversity, paleoecosys- massive accumulation of embryonic shells, tem, and extinction events, a fundamental The report by Sessa eggs and hatchlings are thought to have been knowledge about habitat depth of ammonoids et al. is the first paper to planktic, feeding during early development is crucial. describe the habitat of on planktic microorganisms (12–14). If this ThereportbySessaetal.(1)isthefirst were the case, the abrupt demise of planktic paper to describe the habitat of ammonoids ammonoids in the latest ecosystems at the K/Pg boundary would have in the latest Cretaceous Western Interior Seaway Cretaceous Western In- had a great impact on the survival of newly of North America with a full set of concrete terior Seaway of North hatched ammonoids, but not on the direct- evidence from oxygen isotopic thermometry. developing nautiloids. However, Landman Isotopic temperatures calculated from planktic America with a full set et al. (15) pointed out the differences in foraminifers inhabiting the mixed layer of the of concrete evidence the timing of extinction between cosmo- water column and benthic organisms on the sea politan and endemic ammonoids. Although floor show temperatures of ∼26 °C and ∼19 °C, from oxygen isotopic ∼ both cosmopolitans and endemics share the respectively, indicating 7 °C differences thermometry. similar embryonic shell size, only endemics between surface and bottom waters. The went extinct at the K/Pg boundary, and few mean isotopic temperatures of the latest Cre- expected that marine planktic ecosystem of cosmopolitans survived into the earliest Pa- taceous ammonoids, Eubaculites carinatus microorganisms was severely damaged at leocene, indicating embryonic shell size; hence, and Eubaculites latecarinatus (Turrilitoidea), the K/Pg boundary (11), Kruta et al. (10) embryonic ecology may not have been the and Discoscaphites iris (Scaphitoidea) are es- proposed that the collapse of the ma- key to survival. However, the termination of timated as ∼18 °C, comparable to those of rine planktic food web was the trigger of all ammonoids—including cosmopolitans— benthic organisms (1). In addition to isotopic the ammonoid extinction event. However, results, careful examination of the preservation Tanabe (12) argued that other groups of at the earliest Paleocene ad extremum, and of shell materials excludes potential postmor- ammonoids with a jaw apparatus similar to the survival of the nautiloid cephalopods, temdrift,oftenaconcerninorganismswith modern nautiloids (e.g., phylloceratids and indicate that the fatal ecology for ammo- potentially buoyant shells. These lines of evi- gaudryceratids), which are assumed to prey noids has yet to be identified. The hypothe- dence clearly indicate that these ammonoid on macroorganisms, also became extinct at ses mentioned above can be tested further species were demersal (bottom dwelling) or- the boundary, indicating that feeding habits with developments of new analytical tech- ganisms, providing the first direct evidence of at submature and mature growth stages
Recommended publications
  • First Record of Non-Mineralized Cephalopod Jaws and Arm Hooks
    Klug et al. Swiss J Palaeontol (2020) 139:9 https://doi.org/10.1186/s13358-020-00210-y Swiss Journal of Palaeontology RESEARCH ARTICLE Open Access First record of non-mineralized cephalopod jaws and arm hooks from the latest Cretaceous of Eurytania, Greece Christian Klug1* , Donald Davesne2,3, Dirk Fuchs4 and Thodoris Argyriou5 Abstract Due to the lower fossilization potential of chitin, non-mineralized cephalopod jaws and arm hooks are much more rarely preserved as fossils than the calcitic lower jaws of ammonites or the calcitized jaw apparatuses of nautilids. Here, we report such non-mineralized fossil jaws and arm hooks from pelagic marly limestones of continental Greece. Two of the specimens lie on the same slab and are assigned to the Ammonitina; they represent upper jaws of the aptychus type, which is corroborated by fnds of aptychi. Additionally, one intermediate type and one anaptychus type are documented here. The morphology of all ammonite jaws suggest a desmoceratoid afnity. The other jaws are identifed as coleoid jaws. They share the overall U-shape and proportions of the outer and inner lamellae with Jurassic lower jaws of Trachyteuthis (Teudopseina). We also document the frst belemnoid arm hooks from the Tethyan Maastrichtian. The fossils described here document the presence of a typical Mesozoic cephalopod assemblage until the end of the Cretaceous in the eastern Tethys. Keywords: Cephalopoda, Ammonoidea, Desmoceratoidea, Coleoidea, Maastrichtian, Taphonomy Introduction as jaws, arm hooks, and radulae are occasionally found Fossil cephalopods are mainly known from preserved (Matern 1931; Mapes 1987; Fuchs 2006a; Landman et al. mineralized parts such as aragonitic phragmocones 2010; Kruta et al.
    [Show full text]
  • Paléontologie Au Luxembourg (2) A
    Paléontologie au Luxembourg (2) A. Di Cencio, D. Sadki, R. Weis (eds.) R. Weis D. Sadki, A. Di Cencio, Les ammonites de la Minette Andrea Di Cencio, Driss Sadki, Paléontologie au Luxembourg (2) Luxembourg au Paléontologie Robert Weis (eds.) Ferrantia Travaux scientifiques du Musée national d'histoire naturelle Luxembourg www.mnhn.lu 83 2020 Ferrantia 83 2020 2020 83 Ferrantia est une revue publiée à intervalles non réguliers par le Musée national d’histoire naturelle à Luxembourg. Elle fait suite, avec la même tomaison, aux T M ’ L parus entre 1981 et 1999. Comité de rédaction: Eric Buttini Guy Colling Alain Frantz Thierry Helminger Ben Thuy Mise en page: Romain Bei Design: Thierry Helminger Prix du volume: 20 € Rédaction: Échange: Musée national d’histoire naturelle Exchange MnhnL Rédaction Ferrantia c/o Musée national d’histoire naturelle 25, rue Münster 25, rue Münster L-2160 Luxembourg L-2160 Luxembourg Tél +352 46 22 33 - 1 Tél +352 46 22 33 - 1 Fax +352 46 38 48 Fax +352 46 38 48 Internet: http://www.mnhn.lu/ferrantia/ Internet: http://www.mnhnl.lu/biblio/exchange email: [email protected] email: [email protected] Page de couverture: Bredyia subinsignis (Oppel, 1856), DOU833. Natural History Museum of Luxembourg. Citation: Di Cencio A., Sadki D., Weis R. (eds.) 2020. - Paléontologie au Luxembourg (2) - Les ammonites de la Minette. Ferrantia 83, Musée national d’histoire naturelle, Luxembourg, 129 p. Date de publication: 15 décembre 2020 (réception du manuscrit: 19 mai 2020) Impression: Imprimerie Centrale climatiquement neutre Impression | LU-319-JR8FDJV | www.natureOffice.com Ferrantia est publiée sous la licence Creative Commons BY-NC-ND 3.0 LU.
    [Show full text]
  • Early Bajocian Type Sonniniids and Hammatoceratids SW Germany
    Boletín del Instituto de Fisiografía y Geología 91, 2021 1 New information on the Early Bajocian types of sonniniids and hammatoceratids (Ammonitina) described by W. Waagen (1867) from Gingen/Fils (SW Germany) Driss Sadki & Volker Dietze Sadki D. & Dietze V., 2021. New information on the Early Bajocian types of sonniniids and hammatoceratids (Ammonitina) described by W. Waagen (1867) from Gingen/Fils (SW Germany). Boletín del Instituto de Fisiografía y Geología 91: 1-16. Rosario, 08/05/2021. ISSN 1666-115X. Abstract. The type specimens of the species of sonniniids and hammatoceratids (Ammonitina) from the Lower Bajocian of Gingen/Fils (SW Germany) described by Waagen in 1867, and deposited in the Bavarian State Collection for Palaeontology and Geology in Munich, are revised. They are referred to the morphogenera Euhoploceras, Shirbuirnia, Papilliceras, Sonninia, Witchellia, and Fissilobiceras: E. adicrum (Waagen, 1867), E. polyacanthum (Waagen, 1867), E. mayeri (Waagen, 1867), S. gingensis (Waagen, 1867), P. mesacanthum (Waagen, 1867), S. patella (Waagen, 1867), W. jugifera (Waagen, 1867), and F. fissilobatum (Waagen, 1867). A lectotype is designated for E. Recibido 17/09/2020 Aceptado 29/10/2020 mayeri (Waagen, 1867). Keywords: Sonniniidae ▪ Hammatoceratidae ▪ Ammonitina ▪ Middle Jurassic ▪ Lower Bajocian ▪ W. Waagen ▪ Disponible vía Internet Southwest Germany. & versión impresa 08/05/2021 Resumen. Nueva información sobre los tipos de sonníniidos y hammatocerátidos (Ammonitina, Cephalopoda) del Editor: H. Parent Bajociano Inferior de Gingen/Fils (SO de Alemania) descriptos por W. Waagen (1867). Los especímenes tipo de sonníniidos y hammatocerátidos (Ammonitina) del Bajociano Inferior de Gingen/Fils (SO de Alemania) descriptos por Waagen en 1867, actualmente depositados en el Bayerischen Staatssammlung für Paläontologie und Geologie in München, son revisados y referidos a los morfogéneros Euhoploceras, Shirbuirnia, Papilliceras, Sonninia, Witchellia, y Fissilobiceras: E.
    [Show full text]
  • Abstracts and Program. – 9Th International Symposium Cephalopods ‒ Present and Past in Combination with the 5Th
    See discussions, stats, and author profiles for this publication at: https://www.researchgate.net/publication/265856753 Abstracts and program. – 9th International Symposium Cephalopods ‒ Present and Past in combination with the 5th... Conference Paper · September 2014 CITATIONS READS 0 319 2 authors: Christian Klug Dirk Fuchs University of Zurich 79 PUBLICATIONS 833 CITATIONS 186 PUBLICATIONS 2,148 CITATIONS SEE PROFILE SEE PROFILE Some of the authors of this publication are also working on these related projects: Exceptionally preserved fossil coleoids View project Paleontological and Ecological Changes during the Devonian and Carboniferous in the Anti-Atlas of Morocco View project All content following this page was uploaded by Christian Klug on 22 September 2014. The user has requested enhancement of the downloaded file. in combination with the 5th International Symposium Coleoid Cephalopods through Time Abstracts and program Edited by Christian Klug (Zürich) & Dirk Fuchs (Sapporo) Paläontologisches Institut und Museum, Universität Zürich Cephalopods ‒ Present and Past 9 & Coleoids through Time 5 Zürich 2014 ____________________________________________________________________________ 2 Cephalopods ‒ Present and Past 9 & Coleoids through Time 5 Zürich 2014 ____________________________________________________________________________ 9th International Symposium Cephalopods ‒ Present and Past in combination with the 5th International Symposium Coleoid Cephalopods through Time Edited by Christian Klug (Zürich) & Dirk Fuchs (Sapporo) Paläontologisches Institut und Museum Universität Zürich, September 2014 3 Cephalopods ‒ Present and Past 9 & Coleoids through Time 5 Zürich 2014 ____________________________________________________________________________ Scientific Committee Prof. Dr. Hugo Bucher (Zürich, Switzerland) Dr. Larisa Doguzhaeva (Moscow, Russia) Dr. Dirk Fuchs (Hokkaido University, Japan) Dr. Christian Klug (Zürich, Switzerland) Dr. Dieter Korn (Berlin, Germany) Dr. Neil Landman (New York, USA) Prof. Pascal Neige (Dijon, France) Dr.
    [Show full text]
  • Lower and Middle Jurassic Ammonoids of the Shemshak Group in Alborz, Iran and Their Palaeobiogeographical and Biostratigraphical Importance
    Lower and Middle Jurassic ammonoids of the Shemshak Group in Alborz, Iran and their palaeobiogeographical and biostratigraphical importance KAZEM SEYED−EMAMI, FRANZ T. FÜRSICH, MARKUS WILMSEN, MAHMOUD R. MAJIDIFARD, and ALI SHEKARIFARD Seyed−Emami, K., Fürsich, F.T., Wilmsen, M., Majidifard, M.R., and Shekarifard, A. 2008. Lower and Middle Jurassic ammonoids of the Shemshak Group in Alborz, Iran and their palaeobiogeographical and biostratigraphical importance. Acta Palaeontologica Polonica 53 (2): 237–260. The Shemshak Group at Shahmirzad (northern Iran) is characterized by the most frequent and extensive marine intercala− tions and contains the most abundant and diverse ammonite faunas hitherto known from the Lower and lower Middle Ju− rassic strata of the Alborz Range. So far, 62 ammonite taxa have been recorded from this area, including 25 taxa from ear− lier studies. The taxa belong to the families Cymbitidae, Echioceratidae, Amaltheidae, Dactylioceratidae, Hildoceratidae, Graphoceratidae, Hammatoceratidae, Erycitidae, and Stephanoceratidae with the new species Paradumortieria elmii and Pleydellia (P.?) ruttneri. The fauna represents the Late Sinemurian, Late Pliensbachian, Toarcian, Aalenian, and Early Bajocian. Palaeobiogeographically, it is closely related to the Northwest European (Subboreal) Province, and exhibits only minor relations with the Mediterranean (Tethyan) Province. Key words: Ammonitida, biostratigraphy, palaeobiogeography, Jurassic, Shemshak Group, Alborz Mountains, Iran. Kazem Seyed−Emami [[email protected]] and Ali Shekarifard, School of Mining Engineering, University College of En− gineering. University of Tehran, P.O. Box 11365−4563, Tehran, Iran; Franz T. Fürsich [[email protected]−erlangen.de] and Markus Wilmsen [[email protected]−erlangen.de], Geozentrum Nordbayern der Universität Erlangen−Nürnberg, Fachgruppe PaläoUmwelt, Loewenichstraße 28, D−91054 Erlangen, Germany; Mahmoud R.
    [Show full text]
  • Cretaceous Ammonoids
    COMMENTARY Evolution of habitat depth in the Jurassic– Cretaceous ammonoids Kazuyoshi Moriya1 oxygen isotopic analyses of shell materials of Department of Earth Sciences, Faculty of Education and Integrated Arts and Sciences, ammonoids reveal the temperature at which Waseda University, Shinjuku-ku, Tokyo 169-8050, Japan the shell was secreted. This technique, called oxygen isotopic thermometry, has been widely Ammonoids, a group of cephalopods with body fossils and close modern relatives. For used in paleoclimatological and paleobiologi- external chambered shells, arose in the early example, although one may usually imagine that cal research. It was also applied to ammonoid Devonian and went extinct at the Cretaceous/ ammonoids were planktic or nektic organisms fossils more than 40 y ago (2, 3). Many scien- Paleogene (K/Pg) boundary. During their 340- within a water column, like the Nautilus,which tists, however, assumed that ammonoids were planktic or nektic organisms, so their discus- million-y history, ammonoids suffered three is the sole surviving cephalopod bearing an sion focused mainly on growth rates inferred major diversity crises at the end of the Devonian, external chambered shell, there is very little by identifying sinusoidal patterns, hence sea- Permian, and Triassic Periods, and the terminal direct evidence showing the habitat depth of sonality, in the temperature data. Among extinction event at the K/Pg boundary. Because ammonoids within an ancient water column. those previous workers, Anderson et al. (4) of their rapid morphological evolution and rich Sessa et al. (1) shed new light on the habitat analyzed oxygen isotopic composition of the fossil record, ammonoids have been used to depth of the Cretaceous ammonoids using geo- middle Jurassic ammonoids and compared determine the relative age of marine strata and chemical proxy records.
    [Show full text]
  • Ritterbush, K. A., and M. Foote. 2017. Association Between Geographic
    Paleobiology, 43(2), 2017, pp. 209–223 DOI: 10.1017/pab.2016.25 Association between geographic range and initial survival of Mesozoic marine animal genera: circumventing the confounding effects of temporal and taxonomic heterogeneity Kathleen A. Ritterbush and Michael Foote Abstract.—We investigate the association between geographic range and survival in Mesozoic marine animal genera. Previous work using data from the Paleobiology Database (paleobiodb.org) demonstrated greater survivorship overall among Phanerozoic genera that were widespread during their stage of first appearance, but this relationship did not hold during the Mesozoic. To explore this unexpected result, we consider geographic range in conjunction with temporal variation in survival and variation in survival among higher taxa. Because average range and average survival are negatively correlated among stages, for reasons that are still unclear, and because the data are heavily influenced by cephalopods, which include many wide-ranging and short-lived genera, the effect of geographic range on survival is obscured in the aggregate data. Thus, range is not a significant predictor of survival when data are analyzed in aggregate, but it does have a significant effect when variation in average range and average survival among stages and classes is taken into account. The best-fitting models combine range with both temporal and taxonomic heterogeneity as predictive factors. Moreover, when we take stage-to-stage variation into account, geographic range is an important predictor of survival within most classes. Cephalopod genera must be more widespread than genera in other classes for geographic range to significantly increase odds of survival, and factoring in survival heterogeneity of superfamilies further increases model fit, demonstrating a nested nature in the sensitivity of range and taxonomic aggregation.
    [Show full text]
  • Upper Toarcian – Middle Aalenian (Jurassic) Erycitinae SPATH (Ammonitina) from the Gerecse Mts, Hungary
    GALÁCZ, A. (ed.): 125th Anniversary of the Department of Palaeontology at Budapest University – A Jubilee Volume Hantkeniana 6, 57—108, Budapest, 2008 Upper Toarcian – Middle Aalenian (Jurassic) Erycitinae SPATH (Ammonitina) from the Gerecse Mts, Hungary 1 2 Zoltán KOVÁCS & Barnabás GÉCZY (with 12 figures, 4 tables and 13 plates) The Upper Toarcian–Middle Aalenian sequences of the Gerecse Mts belong to the Mediterranean region of the Mediterran–Caucasian Realm, bigger part of the Ammonoidea collected here are represented by the suborders Phylloceratina and Lytoceratina. In this paper the species belonging to the subfamily Erycitinae SPATH are documented as a contribution to the general taxonomic and biostratigraphic revision of the Ammonitina fauna. Considering the abundance and diversity of the subfamily, it was a dominant group in the Meneghinii to Opalinum Zones: during its acme Erycitinae formed 52% of the Ammonitina. Two genera, one subgenus and 15 species are represented by 117 determined specimens. Quantitative evaluation and problems of systematics are briefly discussed, genera and species are described. Introduction of two new taxa, Cagliceras enigmaticum n. sp. and Erycites gerecsensis n. sp. is designated. Key words: Ammonitina, Erycitinae, Cagliceras, Erycites, Abbasitoides, Jurassic, Toarcian, Aalenian, Gerecse Mts, Hungary Introduction The present study is a contribution to the SZENTE (2007) completed a detailed revision of the documentation and biostratigraphic and paleobio- Middle Toarcian (Bifrons and Gradata Zones) geographic investigation of the Toarcian and Aalenian Ammonitina fauna, and discussed its Ammonitina fauna of the Gerecse Mts. An extensive paleobiogeographic consequences. The aim of this collecting work was carried out in five sections of the paper is to provide quantitative and biostratigraphic Gerecse Mts (Figure 1) between 1976-1982, by the evaluation as well as taxonomic documentation of staff of the Geological Institute of Hungary.
    [Show full text]
  • (Ammonoidea, Hildoceratidae) Del Toarciense En Las
    Original article Paroniceratinae (Ammonoidea, Hildoceratidae) del Toarciense en las Cordilleras Ibérica y Cantábrica (España)§ Panoniceratinae (Ammonoidea, Hildoceratidae) of the Toarcian of Iberian and Cantabrian Ranges (Spain) Paroniceratinae (Ammonoidea, Hildoceratidae) du Toarcien des Cordillères ibérique et cantabrique (Espagne) Antonio Goy, Gemma Martínez * Departamento de Paleontología e Instituto de Geología Económica, Facultad de Ciencias Geológicas, Univesidad Complutense, Ciudad Universitaria, 28040 Madrid, España Recibido el 29 de julio 2008; aceptado en el 6 de marzo 2009 Disponible en lı´nea 30 de junio 2009 Resumen Los Paroniceratinae constituyen un grupo que tiene un registro amplio en el dominio del Tethys. Sin embargo, representan menos del 1% de los ammonoideos obtenidos en materiales del Toarciense de las regiones situadas al este de la Meseta Ibérica (Cordillera Ibérica). Los valores son aun menores en las regiones del norte (Cordillera Cantábrica) y del oeste (Portugal), y muestran una presencia esporádica en la Cordillera Bética. En este estudio se revisa la distribución bioestratigráfica y la posición biocronoestratigráfica de las especies registradas en las secciones expandidas más representativas de España y se compara con la que tienen en otras áreas de las bioprovincias del NW de Europa y del Tethys. Se describen y figuran los especímenes de Frechiella: F. subcarinata (Young y Bird), F. helenae Renz, F. venantii (Catullo), F. kammerkarensis (Stolley) y F. cf. octaviae Renz, procedentes de materiales de la Zona Bifrons en la Cordillera Ibérica, así como los de Paroniceras: P. sternale (d’Orbigny) y P. helveticum Renz, y Oxyparoniceras: O. (O.) cf. telemachi (Renz), O. (O.) buckmani (Bonarelli), O. (N.) cf. undulosum (Monestier), O.
    [Show full text]
  • Late Toarcian - Late Aalenian Ammonites Assemblage from Mt
    Geologica Romana 37 (2003-2004), 1-66 LATE TOARCIAN - LATE AALENIAN AMMONITES ASSEMBLAGE FROM MT. MAGAGGIARO (WESTERN SICILY, ITALY) Giovanni Pallini*†, Serge Elmi** & Francesca Gasparri*** * Università degli Studi di Chieti “Gabriele D’Annunzio”, Via dei Vestini, 27 - Chieti ** Université “Claude Bernard” Lyon 1, UFR des Sciences de la Terre, 27-43 Bd. du 11 Novembre 1918, 69622 Villeurbanne Cedex -France, e-mail: [email protected] *** Via Alessandria, 154 - 00198 Roma, e-mail: [email protected] ABSTRACT - This study describes a condensed and reworked ammonites assemblage found in a quarry loca- ted south of Mt. Magaggiaro (Trapani). The specimens were collected from a pocket filled by multiple polymetal- lic crusts and stromatolites and sandwiched between shallow-water platform sediments (carbonates of the Sciacca Formation and Inici Formation) and overlying pelagic deposits (limestones and marly limestones - the Ammonitico Rosso Formation). All the specimens (145 representing 29 genera, 3 subgenera, 39 species and 15 subspecies) have normal species size; adult specimens of large dimensions are also present. The ammonites are very well preserved, someones with iridescent shells. The species range from the Meneghinii Zone to the Concavum Zone (Late Toarcian-Late Aalenian). The assemblage is very similar to that collected by Vacek (1886) and De Gregorio (1886 b), differing however for the presence of many Phylloceratids, rare at Cape San Vigilio, whereas other forms (Dumortieria spp. and Polyplectus spp.), abundant in Sicily, lack at Cape San Vigilio. Oppelids are not present in Sicily. A seaway probably existed, connecting the two areas (today > 1000 km apart) and allowing for an unconstrained pattern of areal distribution of ammonite species.
    [Show full text]
  • Ammonites, Taphonomical Analysis and Biostratigraphy of the Aalenian (Middle Jurassic) from Capo San Vigilio (Lake Garda, N Italy)
    AperTO - Archivio Istituzionale Open Access dell'Università di Torino Ammonites, taphonomical analysis and biostratigraphy of the Aalenian (Middle Jurassic) from Capo San Vigilio (Lake Garda, N Italy) This is a pre print version of the following article: Original Citation: Availability: This version is available http://hdl.handle.net/2318/1666420 since 2018-04-06T18:04:22Z Published version: DOI:10.1127/njgpa/2017/0657 Terms of use: Open Access Anyone can freely access the full text of works made available as "Open Access". Works made available under a Creative Commons license can be used according to the terms and conditions of said license. Use of all other works requires consent of the right holder (author or publisher) if not exempted from copyright protection by the applicable law. (Article begins on next page) 05 October 2021 1 This is the author's final version of the contribution published as: DIETZE V., CRESTA S., MARTIRE L. & PAVIA G. Ammonites, taphonomical analysis and biostratigraphy of the Aalenian (Middle Jurassic) from Capo San Vigilio (Lake Garda, N Italy). ). N. Jb. Geol. Paläont. Abh. 284/2, 2017, pagg. 161- 206. DOI 10.1127/njgpa/2017/0657 The publisher's version is available at: https://www.schweizerbart.de/papers/njgpa/detail/284/87509/Ammonites_ta phonomical_analysis_and_biostratigraphy_of_the_Aalenian_Middle_Jurassic_f rom_Capo_San_Vigilio_Lake_Garda_N_Italy When citing, please refer to the published version. Link to this full text: hdl:2318/1666420 This full text was downloaded from iris-Aperto: https://iris.unito.it/ 2 Ammonites, taphonomical analysis and biostratigraphy of the Aalenian (Middle Jurassic) from Capo San Vigilio (Lake Garda, N Italy) Volker Dietze (1*), Stefano Cresta (2), Luca Martire (3), Giulio Pavia (3) (1) Meraner Str.
    [Show full text]
  • The Dorsal Shell Wall Structure of Mesozoic Ammonoids
    The dorsal shell wall structure of Mesozoic ammonoids GREGOR RADTKE and HELMUT KEUPP Radtke, G. and Keupp, H. 2017. The dorsal shell wall structure of Mesozoic ammonoids. Acta Palaeontologica Polonica 62 (1): 59–96. The study of pristine preserved shells of Mesozoic Ammonoidea shows different types of construction and formation of the dorsal shell wall. We observe three major types: (i) The vast majority of Ammonoidea, usually planispirally coiled, has a prismatic reduced dorsal shell wall which consists of an outer organic component (e.g., wrinkle layer), which is the first layer to be formed, and the subsequently formed dorsal inner prismatic layer. The dorsal mantle tissue suppresses the formation of the outer prismatic layer and nacreous layer. With the exception of the outer organic component, secretion of a shell wall is omitted at the aperture. A prismatic reduced dorsal shell wall is always secreted immediately after the hatching during early teleoconch formation. Due to its broad distribution in (planispiral) Ammonoidea, the prismatic reduced dorsal shell wall is probably the general state. (ii) Some planispirally coiled Ammonoidea have a nacreous reduced dorsal shell wall which consists of three mineralized layers: two prismatic layers (primary and secondary dorsal inner prismatic layer) and an enclosed nacreous layer (secondary dorsal nacreous layer). The dorsal shell wall is omitted at the aperture and was secreted in the rear living chamber. Its layers are a continuation of an umbilical shell doubling (reinforcement by additional shell layers) that extends towards the ventral crest of the preceding whorl. The nacreous reduced dorsal shell wall is formed in the process of ontogeny following a prismatic reduced dorsal shell wall.
    [Show full text]