PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Powiadomienia systemowe
  • Sesja wygasła!
Tytuł artykułu

Konkrecje hiatusowe z iłów rudonśnych Wyżyny Krakowsko-Częstochowskiej

Treść / Zawartość
Identyfikatory
Warianty tytułu
EN
Hiatus concretions fromthe ore-bearing clays of the Cracow-Czestochowa Upland (Polish Jura)
Języki publikacji
PL
Abstrakty
EN
Hiatus concretions are arly-diagenetic sedimentary bodies, which in their history of formation, underwent exhumation during sedimentation break and/or erosion of sea-floor. Then they were colonized by various encrusters and borers, before they were buried again. Within Middle Jurassic (Bajocian through Bathonian) clays, hiatus concretions occur in four localities in the Cracow-Częstochowa Upland (south and central Poland): Ogrodzieniec, Bugaj, Mokrsko and Krzyworzeka. Preliminary data about their mineralogy, organic geochemistry and palaeoecology is given. Mineralogical analyses showed, that except dominant high Mg-calcite (up to 87.10% of total carbonates), concretions possess minor amounts of such compounds as quartz, clay minerals (kaolinite and illite), pyrite, siderite or Mg-kutnahorite. However, high differences are observed between total organic carbon contents of concretions (TOC=0.46%) and surrounded clays (TOC = 2.16%), but their molecular composition is similar. Most of identified biomarkers are of terrestrial origin. In clay lithology, the hiatus concretions are the only sedimentary bodies that clearly mark the sedimentation pauses (hiatuses). In the investigated area, they form more or less continuous horizons. The concretions are calcitic, possessing various encrusting fauna such as bryozoans, oysters and oyster-like bivalves, serpulids, solitary corals and foraminifers. They often post-date the borings, belonging to such ichnogenera as Gastrochaenolites, Trypanites and Entobia. Some of the nodules show distinct transition from firmground (characterized by the presence of Glossifungites ichnocoenosis) to hardground (presence of Trypanites ichnocoenosis), pointing to the fact, that they formed at, or very close to, the sediment-water interface. Some concretions, like those from Bugaj and Mokrsko, are characterized by their high diversity of hard bottom communities. Those concretions are also irregular in shape; others, like those from Ogrodzieniec and Krzyworzeka, possess lower diversity. The concretions from Krzyworzeka are especially dominated by the borers, while the encrusters are sparse and not diverse. Those nodules that are wide and flat tend to be more bored on one surface only, while those that are more roundish, are bored on both sides more evenly. The degree of diversity is probably correlated with physical disturbance, causing the rolling and overturning of the exhumed concretions in the littoral zone. On the other hand, the overall diversity could be lowered due to destructive abrasion either of the shallowest borings, echinoid/gastropod scratch marks and shells of nestling bivalves, as well as more delicate epilithozoans.
Rocznik
Strony
131--138
Opis fizyczny
fot., wykr., bibliogr. 46 poz.
Twórcy
autor
autor
Bibliografia
  • BAIRD G.C. 1976 - Coral encrusted concretions: a key to recognition of a 'shale on shale' erosion surface. Lethaia, 9: 293-302.
  • BAIRD G.C. 1981 - Submarine erosion on a gentle paleoslope: a study of two discontinuities in the New York Devonian. Lethaia, 14: 105-122.
  • BAIRD G.C. & FÜRSICH F.T. 1975 - Taphonomy and biologic progression associated with submarine erosion surfaces from the German Lias. Neues Jahrb. Geol. und Paläont., Monatschefte, H.6: 321-338.
  • BENNER J.S., EKDALE A.A. & DE GIBERT J.M. 2004 - Macroborings (Gastrochaenolites) in Lower Ordovician hardgrounds of Utah: sedimentologic, paleoecologic, and evolutionary implications. Palaios, 19: 543-550.
  • BERNER R.A. 1968 - Calcium carbonates concretions formed by the decomposition of organic matter. Science, 159: 195-197.
  • BOJESEN-KOEFOED J.A.1996 - Organic geochemical screening analysis of outcrop samples. EFP-95Project: The Polish Middle to Late Jurassic epicratonic basin, stratigraphy and basin history. GEUS Raport, 1996/81: 1-30.
  • BRASSELL S.C., EGLINTON G. & MO F.J. 1986 - Biological marker compounds as indicators of the depositional history of the Maoming oil shale. Organic Geochemistry, 10: 927-941.
  • BRAY E.E. & EVANS E.D. 1961 - Distribution of n-paraffins as a clue to recognition of source beds. Geochimica et Cosmochimica Acta, 22: 2-15.
  • BROMLEY R.G. 1970 - Borings as trace fossils and Entobia cretacea Portlock, as an example. [In:] Crimes T.P. & Harper J.C. (eds.), Trace Fossils. Geol. Jour. Spec. Issue, 3: 49-90.
  • BROMLEY R.G. 1991- The palaeoecology of bioerosion. [In:] Donovan S.K. (ed.), The Palaeobiology of Trace Fossils. John Wiley & Sons: 134-154.
  • BROMLEY R.G. 2004 - A stratigraphy of marine bioerosion. [In]: McIlroy D. (ed.) - The application of ichnology to palaeoenvironmental and stratigraphic analyses. Geol. Soc., London, Spec. Publ., 228: 455-479.
  • BROMLEY R.G. & ASGAARD U. 1993 - Two bioerosion ichnofacies produced by early and late burial associated with sea-level change. Geol. Rundschau, 82: 276-280.
  • DAYCZAK-CALIKOWSKA K., KOPIK J. & MARCINKIEWICZ T. 1997 - Middle Jurassic. [In]: Marek S. & Pajchlowa M. (eds.), The epicontinental Permian and Mesozoic in Poland. Pr. Państw. Inst. Geol., 153: 236-282.
  • DOVAL M. & GALAN E. 1976 - Aplication del a diffraccion de rayos X al. Estudio de la composition quimica de carbonatos romboedricos naturales. Boll. Soc. Esp. Ceram. y viadro, 15: 27-30.
  • GINGRAS M.K., PEMBERTON S.G. & SAUNDERS T. 2001 - Bathymetry, sediment texture, and substrate cohesiveness; their impact on modern Glossifungites trace assemblages at Willapa Bay, Washington. Palaeogeography, Palaeoclimatology, Palaeoecology, 169: 1-21.
  • HAHN W., WESTERMANN G.E.G. & JORDAN R. 1990 - Ammonite fauna of the Upper Bathonian hodsoni Zone (Middle Jurassic) at Lechstedt near Hildesheim, Northwest Germany. Geol. Jahrb., A121: 21-63.
  • HALLAM A. 1969 - A pyritized limestone hardground in the Lower Jurassic of Dorset (England). Sedimentology, 12: 231-240.
  • HESSELBO S.P. & PALMER T.J. 1992 - Reworked early diagenetic concretions and the bioerosional origin of a regional discontinuity within British Jurassic marine mudstones. Sedimentology, 39: 1045-1065.
  • JIANG CH., ALEXANDER R., KAGI R.I. & MURRAY A.P. 2000 - Origin of perylene in ancient sediments and its geological significance. Organic Geochemistry, 31: 1545-1559.
  • FREY R.W. & SEILACHER A. 1980 - Uniformity in marine invertebrate ichnology. Lethaia, 13: 183-207.
  • FREY R.W., PEMBERTON S.G. & SAUNDERS T.D.A. 1990 - Ichnofacies and bathymetry: a passive relationship. Jour. Paleont., 64: 155-158.
  • FÜRSICH F.T. 1979 - Genesis, environments, and ecology of Jurassic hardgrounds. Neues Jahrb. Geol. Paläont., Abh., 158: 1-63.
  • KAŹMIERCZAK J. 1974 - Crustacean associated hiatus concretions and eogenetic cementation in the Upper Jurassic of central Poland. Neues Jahrb. Geol. Paläont., Abh., 147: 329-342.
  • KENNEDYW.J. & KLINGER H.C. 1972 - Hiatus concretions and hardground horizons in the Cretaceous of Zululand (South Africa). Palaeontology, 15: 539-549.
  • KENNEDYW.J., LINDHOLM R.C., HELMOLD K.P. & HANCOCK J.M. 1977 - Genesis and diagenesis of hiatus- and breccia-concretions from the mid-Cretaceous of Texas and northern Mexico. Sedimentology, 24: 833-844.
  • KOPIK J. 1998 - Jura dolna i oerodkowa północno-wschodniego obrzeżenia Górnoslaskiego Zagłębia Węglowego. Pr. Państw. Inst. Geol., 378: 67-130.
  • MAJEWSKI W. 2000 - Middle Jurassic concretions from Częstochowa (Poland) as indicators of sedimentation rates. Acta Geol. Pol., 50: 431-439.
  • MANGOLD C. & RIOULT M. 1998 - Bathonien. [In:] Cariou E. & Hantzpergue P. (eds.), Biostratigraphie du Jurassiques ouest-européen et méditerranéen. Bull. Cent. Rech. Elf Explor. Prod., Mém., 17: 55-62.
  • MARYNOWSKI L., ROSPONDEK M.J., MEYER ZU RECKENDORF R. & SIMONEIT B.R.T. 2002 - Phenyldibenzofurans and phenyldibenzothiophenes in marine sedimentary rocks and hydrothermal petroleum. Organic Geochemistry, 33: 701-714.
  • MATYJA B.A. & WIERZBOWSKI A. 2000 - Ammonites and stratigraphy of the uppermost Bajocian and Lower Bathonian between Częstochowa and Wieluń, Central Poland. Acta Geol. Pol., 50: 191-209.
  • OTTO A. & SIMONEIT B.R.T. 2001- Chemosystematics and diagenesis of terpenoids in fossil conifer species and sediment from the Eocene Zeitz formation, Saxony, Germany. Geochimica et Cosmochimica Acta, 65: 3505-3527.
  • PALMER T.J. & WILSON M.A. 2004 - Calcite precipitation and dissolution of biogenic aragonite in shallow Ordovician calcite seas.Lethaia, 37: 417-427.
  • POULSEN N.S. 1998 - Upper Bajocian to Callovian (Jurassic) dinoflagellate cysts from central Poland. Acta Geol. Pol., 48: 237-245.
  • RADWAŃSKI A. 1970 - Dependence of rock-borers and burrowers on the environmental conditions within the Tortonian littoral zone of Southern Poland. [In:] Crimes T.P. & Harper J.C. (eds.), Trace Fossils. Geol. Jour. Spec. Iss., 3: 371-390.
  • RAISWELL R. 1987 - Non-steady state microbiological diagenesis and the origin of concretions and nodular limestones. [In:] Marshall J.D. (ed.), Diagenesis of sedimentary sequences. Geol. Soc. Spec. Publ., 36: 41-54.
  • SAVRDA C.E. 1995 - Ichnologic applications in palaeoceanographic, palaeoclimatic, and sea-level studies. Palaios, 10: 565-577.
  • SAVRDA C.E. & BOTTJER D.J. 1988 - Limestone concretion growth documented by trace-fossil relations. Geology, 16: 908-911.
  • TAPANILA L., ROBERTS E.M., BOUARÉ M.L., SISSOKO F. & O'LEARY M.A. 2004 - Bivalve borings in phosphatic coprolites and bone, Cretaceous-Paleogene, Northeastern Mali. Palaios, 19: 565-573.
  • TAYLOR P.D. & WILSON M.A. 2002 - A new terminology for marine organisms inhabiting hard substrates. Palaios, 17: 522-525.
  • TAYLOR P.D. & WILSON M.A. 2003 - Palaeoecology and evolution of marine hard substrate communities. Earth-Sc. Rev., 62: 1-103.
  • VOIGT E. 1968 - Über-Hiatus-Konkretion (dargestellt am Beispielen aus dem Lias): Geol. Rundschau, 58: 281-296.
  • WETZEL A. & ALLIA V. 2000 - The significance of hiatus beds in shallow-water mudstones: an example from the Middle Jurassic of Switzerland. Jour. Sedim. Res., 70: 170-180.
  • WILSON M.A. 1986 - Coelobites and spatial refuges in a lower Cretaceous cobble-dwelling hardground fauna. Palaeontology, 29: 691-703.
  • WILSON M.A. 1987 - Ecological dynamics on pebbles, cobbles, and boulders. Palaios, 2: 594-599.
  • WILSON M.A. & TAYLOR P.D. 2001- Palaeoecology of hard substrate faunas from the Cretaceous Quahlah Formation of the Oman Mountains. Palaeontology, 44: 21-41.
  • ZATOŃ M. & MARYNOWSKI L. 2004 - Konzentrat-Lagerstatte - type carbonate concretions from the uppermost Bajocian (Middle Jurassic) of the Częstochowa area, South-Central Poland. Geol. Quart., 48: 339-350.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BUS2-0011-0032
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.