Journal of Paleolimnology

, Volume 59, Issue 1, pp 21–38 | Cite as

Sedimentology of the Early Jurassic limestone beds of the Kota Formation: record of carbonate wetlands in a continental rift basin of India

  • Suparna Goswami
  • Elizabeth Gierlowski-Kordesch
  • Parthasarathi Ghosh
Original paper

Abstract

Pranhita–Godavari is one of the major rift basins of peninsular India that was actively filled when the Indian landmass was a part of Gondwanaland, the southern supercontinent. The basin-fill succession of this continental rift basin is characterized mainly by fluvial sandstones and mudstones. In the Early Jurassic this basin hosted a freshwater carbonate deposit characterized by a 20–30 m thick alternation of laminated and massive limestones. The remains and traces of land vertebrates, invertebrates and plants suggest that this limestone serves as one of the rare examples of freshwater carbonate depositing environment within a continental rift basin. The limestone interval is characterized by repeatedly stacked meter-thick laminated and massive carbonate-rich sediments. These sediments are classified into two facies associations representing two main depositional domains of a rift-bound, large, freshwater wetland system: a shallow lacustrine palaeoenvironment and a palustrine paleoenvironment. The former palaeoenvironment is characterized by laminated carbonate facies and the later one is by mottled, nodular and bioturbated limestone. Repeated influx of siliclastics by surface flow into ca-rich water bodies produced the laminated carbonates. Whereas, subaerial modifications and reworking of primary deposits resulted in palustrine carbonates. Vertebrate tracks, evidences of rooting, and the absence of deep basinal facies in this succession along with repetitive stacking of sediments formed in subaqueous and subaerial conditions indicates that the depositional environment was more akin to a modern wetland. This Jurassic carbonate wetland developed in the rift basin when the watershed on the adjacent rift shoulder exposed Proterozoic carbonate rocks that provided the ions necessary for carbonate accumulation. The repeated stacking of meter-scale lacustrine and palustrine carbonates in this limestone reflect long-periodicity fluctuations in water level possibly related to subsidence events of the rift valley.

Keywords

Wetland Palustrine Lacustrine Paleohydrology Jurassic Rift basin Gondwana 

Notes

Acknowledgments

Authors thank Indian Statistical Institute, Kolkata for providing necessary infrastructural facilities and financial support for this work. The authors are grateful to Dr. Soumen Sarkar for suggestions. We would also like convey our special thanks to Dr. Dhiraj K. Rudra and Pradip K. Maulik for much helpful discussion. Suggestions of the reviewers helped immensely in improving this manuscript.

References

  1. Alonso-Zarza AM (2003) Palaeoenvironmental significance of palustrine carbonates and calcretes in the geological record. Earth-Sci Rev 60:261–298CrossRefGoogle Scholar
  2. Alonso-Zarza AM, Wright VP (2010) Palustrine carbonates. In: Alonso-Zarza AM, Tanner L (eds) Carbonates in continental settings. Facies, environments and processes, Dev Sedimentol, vol 61, pp 103–131Google Scholar
  3. Alonso-Zarza AM, Dorado-Valino M, Valdeolmillos-Rodríguez A, Ruiz-Zapata MB (2006) A recent analogue for palustrine carbonate environments: the Quaternary deposits of Las Tablas de Daimiel wetlands, Ciudad Real, Spain. In: Alonso-Zarza AM, Tanner LH (eds) Paleoenvironmental record and applications of calcretes and palustrine carbonates. Geological Society of America, Special Paper 416, pp 153–168Google Scholar
  4. Alonso-Zarza AM, Meléndez A, Martín-García R, Herrero MJ, Martín-Pérez A (2012) Discriminating between tectonism and climate signatures in palustrine deposits: lessons from the Miocene of the Teruel Graben, NE Spain. Earth Sci Rev 113:141–160CrossRefGoogle Scholar
  5. Bandyopadhyay S (2011) Non-marine Triassic vertebrates of India, 33-46. In: Calvo LO, Porfiri JO, Gonzalez J, Santos DD (eds) Paleontología y dinosarios desde América Latina. EDIUNC, Editorial de la Universidad Nacional de Cuyo, Mendoza, p 296Google Scholar
  6. Bandyopadhyay S, Gillette DD, Ray S, Sengupta DP (2010) Osteology of Barapasaurustagori (Dinosauria: Sauropoda) from the Early Jurassic of India. Palaeontology 53:533–569CrossRefGoogle Scholar
  7. Bhattacharya A, Ray S, Datta PM, Maulik PK (1994) Fossil Charophyta from the Kota Formation of the Pranhita-Godavari Valley, Andhra Pradesh, India. Ninth International Gondwana symposium, Hyderabad, India, pp 471–475Google Scholar
  8. Bosak T, Souza-Egipsy V, Corsetti FA, Newman DK (2004) Micrometer-scale porosity as a biosignature in carbonate crusts. Geology 32(9):781–784CrossRefGoogle Scholar
  9. Buscalioni AD, Fregenal-Martínez MA (2010) A holistic approach to the palaeoecology of Las Hoyas Konservat-Lagerstätte (La Huérguina Formation, Lower Cretaceous, Iberian Ranges, Spain). J Iberian Geol 36(2):297–326CrossRefGoogle Scholar
  10. Chakraborty C, Mandal N, Ghosh SK (2003) Kinematics of the Gondwana basins of peninsular India. Tectonophysics 377:299–324CrossRefGoogle Scholar
  11. Chaudhuri AK, Deb G, Patranabish-Deb S, Sarkar S (2012) Palaeogeographic and tectonic evolution of the Pranhita-Godavari Valley, central India: a stratigraphic perspective. Am J Sci 312:766–815CrossRefGoogle Scholar
  12. Cowardin LM, Carter V, Golet FC, LaRoe ET (1979) Classification of Wetlands and Deepwater Habitats of the United States: U.S. Fish and Wildlife Service FWS/OBS-79/31: 131Google Scholar
  13. Day SD, Wiseman PE, Dickinson SB, Harris JR (2010) Contemporary concepts of root system architecture of urban trees. Arboriculture & Urban Forestry 36:149–159Google Scholar
  14. Durrance EM (1965) Cone-in-cone structures: a new investigation. Proc Geol Assoc 76:83–90CrossRefGoogle Scholar
  15. Franks PC (1969) Nature, origin, and significance of cone-in-cone structures in the Kiowa Formation (early cretaceous), north-central Kansas. J Sediment Petrol 39:1438–1454Google Scholar
  16. Fregenal-Martinez MA, Melendez N (1994) Sedimentological analysis of the Lower Cretaceous lithographic limestones of the “Las Hoyas” fossil site (Serrenia de Cuenca, Iberian Range, Spain). Geobios 16:185–193CrossRefGoogle Scholar
  17. Freytet P (1973) Petrography and paleo-environment of continental carbonate deposits with particular reference to the Upper Cretaceous and Lower Eocene of Languedoc (Southern France). Sed Geol 10:25–60CrossRefGoogle Scholar
  18. Freytet P, Plaziat JC (1982) Continental carbonate sedimentation and pedogenesis—Late Cretaceous and Early Tertiary of southern France. Contrib Sedimentol 12:213Google Scholar
  19. Freytet P, Verrecchia EP (2002) Lacustrine and palustrine carbonate petrography: an overview. J Paleolimnol 27:221–237CrossRefGoogle Scholar
  20. Gierlowski-Kordesch E (2010) Lacustrine carbonates. In: Alonso-Zarza AM, Tanner L (eds) Carbonates in continental settings. Facies, environments and processes, Dev. Sedimentol vol 61, pp 2–101Google Scholar
  21. Glenn C, Kelts K (1991) Sedimentary rhythms in lake deposits. In: Einsele G, Ricken W, Seilacher A (eds) Cycles and events in stratigraphy. Springer, Berlin, pp 188–221Google Scholar
  22. Gomez Fernández JC, Meléndez N (1991) Rhythmically-laminated lacustrine carbonates in the Lower Cretaceous of La Serrania de Cuenca Basin (Iberian Ranges, Spain). IAS Spec. Publ. 13:245–256Google Scholar
  23. Govindan A (1975) Jurassic freshwater Ostracods from the Kota limestone of India. Palaeontology 18(1):207–216Google Scholar
  24. Hillier RD, Edwards D, Morrissey LB (2008) Sedimentological evidence for rooting structures in the Early Devonian Anglo-Welsh Basin (UK), with speculation on their producers. Palaeogeogr Palaeoclimatol Palaeoecol 270:366–380CrossRefGoogle Scholar
  25. Jain SL (1973) New specimens of Lower Jurassic holostean fishes from India. Palaeontology 16:149–177Google Scholar
  26. Jain SL (1974) Jurassic pterosaur from India. J Geol Soc India 15:334–335Google Scholar
  27. Jain SL (1983) A review of the genus Lepidotes (Actinopteryhii: Semionotiformes) with special reference to the species from Kota Formation (Lower Jurassic), India. J Palaeontol Soc India 28:7–42Google Scholar
  28. King W (1981) The geology of the Pranhita-Godavari Valley. Mem Geol Surv India 18(pt. 3):1–161Google Scholar
  29. Klappa CF (1980) Rhizoliths in terrestrial carbonates: classification, recognition, genesis and significance. Sedimentology 27:613–629CrossRefGoogle Scholar
  30. Kraus MJ, Hasiotis ST (2006) Significance of different modes of rhizolith preservation to interpreting paleoenvironmental and paleohydrologic settings: examples from Paleogene paleosols, Bighorn Basin, Wyoming, USA. J Sediment Res 76:633–646CrossRefGoogle Scholar
  31. Kutty TS, Sengupta DP (1989) The Late Triassic formations of the Pranhita Godavari valley and their vertebrate faunal succession: a reappraisal. Indian J Earth Sci 16:189–206Google Scholar
  32. Maulik PK, Rudra DK (1986) Trace fossils from the freshwater Kota Limestone of the Pranhita-Godavari valley, south central India. Bull Geol Min Met Soc India 54:114–123Google Scholar
  33. Melendez N, Liesa CL, Soria AR, Melendez A (2009) Lacustrine system evolution during early rifting: El Castellar Formation (Galvesubbasin, Central Iberian Chain). Sed Geol 222:64–77CrossRefGoogle Scholar
  34. Noffke N, Gerdes G, Klenke T, Krumbein WE (2001) Microbially induced sedimentary structures: a new category within the classification of primary sedimentary structures. J Sediment Res 71:649–656CrossRefGoogle Scholar
  35. Novas FE, Ezcurra MD, Chatterjee S, Kutty TS (2011) New Dinosaur species from the Upper Triassic Upper Maleri and Lower Dharmaram formations of central India. Trans R Soc Edinburgh 101:333–349Google Scholar
  36. PiPujol MD, Buurman P (1997) Dynamics of iron and calcium carbonate redistribution and palaeohydrology in middle Eocene alluvial paleosols of the southeast Ebro Basin margin (Catalonia, northeast Spain). Palaeogeogr Palaeoclimatol Palaeoecol 134:87–107Google Scholar
  37. Pla-Pueyo S, Gierlowski-Kordesch EH, Viseras C, Soria JM (2009) Major controls on carbonate deposition during the evolution of a continental basin: Pliocene-Pleistocene of the Guadix Basin (Betic Cordillera, southern Spain). Sed Geol 219:97–114CrossRefGoogle Scholar
  38. Pla-Pueyo S, Viseras C, Candy I, Soria JM, García-García F, Schreve D (2015) Climatic control on palaeohydrology and cyclical sediment distribution in the Plio-Quaternary deposits of the Guadix Basin (Betic Cordillera, Spain). Quatern Int 389:56–69CrossRefGoogle Scholar
  39. Platt NH, Wright VP (1991) Lacustrine carbonates: facies models, facies distributions and hydrocarbon aspects. In: Anadon P, Cabrera L, Kelts K (eds) Lacustrine Facies Analysis, IAS Spec. Publ vol 13, pp 57–74Google Scholar
  40. Platt NH, Wright VP (1992) Palustrine carbonates and the Florida everglades: towards an exposure index for the fresh-water environment? J Sediment Petrol 62(6):1058–1071Google Scholar
  41. Prasad GVR (2001) Age of Kota Formation, Pranhita-Godavari Valley, India: a palynological approach. J Palaeontol Soc India 46:77–93Google Scholar
  42. Quiajada E, Suarez-Gonzalez P, Isabel Benito M, Mas R (2013) Depositional depth of laminated carbonate deposits: insights from the Lower Cretaceous Valdeprado Formation (Cameros basin, northern Spain). J Sediment Res 83:241–257CrossRefGoogle Scholar
  43. Robinson PL (1967) The Indian Gondwana formations: a review. First Symposium on Gondwana Stratigraphy, Mar Del Plata, Argentina. UNESCO, Paris, pp 201–268Google Scholar
  44. Rosen MR, Arehart GB, Lico MC (2004) Exceptionally fast growth rate of, 100-yr-old tufa, Big Soda Lake, Nevada: implications for using tufa as a paleoclimate proxy. Geology 32(5):409–412CrossRefGoogle Scholar
  45. Rudra DK (1982) Upper Gondwana stratigraphy and sedimentation in the Pranhita-Godavari valley, India. Quart J Geol Min Met Soc India 54:56–79Google Scholar
  46. Rudra DK, Maulik PK (1987) Stromatolites from Jurassic freshwater limestones, India. Mesozoic Res. 1:135–146Google Scholar
  47. Rudra DK, Maulik PK (1994) Lower Jurassic Kota Limestone of India. Global Geol Record Lake Basins 1:185–191Google Scholar
  48. Saez A, Valero-garce BL, Moreno A, Bao R, Pueyo JJ, Gonzálezsamperi P, Giralt S, Taberner C, Herrera C, Gibert O (2007) Lacustrine sedimentation in active volcanic settings: the Late Quaternary depositional evolution of Lake Chungará (northern Chile). Sedimentology 54:1191–1222Google Scholar
  49. Schieber J (1986) The possible role of benthic microbial mats during the formation of carbonaceous shales in shallow Mid-Proterozoic basins. Sedimentology 33:521–536CrossRefGoogle Scholar
  50. Smoot J (1983) Depositional subenvironments in an arid closed basin: wilkins Peak Member of the Green River Formation (Eocene), Wyoming, U.S.A. Sedimentology 30:801–827CrossRefGoogle Scholar
  51. Tanner EH (2000) Palustrine–lacustrine and alluvial facies of the (Norian) Owl Rock Formation (Chinle Group), Four Corners Region, Southwestern U.S.A: Implications for Late Triassic Paleoclimate. J Sediment Res 70(6):1280–1289Google Scholar
  52. Tasch P, Sastry MVA, Shah SC, Rao BRJ, Rao CN, Ghosh SC (1975) Estherids of the Indian Gondwanas: significance for continental fit. In: Advances in stratigraphy and palaeontology, pp 443–452Google Scholar
  53. Wright VP (1990) Syngenetic formation of grainstones and pisolites from fenestral carbonates in peritidal settings: discussion. J Sediment Petrol 60:309–310CrossRefGoogle Scholar
  54. Yadagiri P, Rao BRJ (1987) Contribution to the statigraphy and vertebrate fauna of lower Jurassic Kota Formation, Pranhita-Godavari valley, India. Palaeobot 36:230–244Google Scholar
  55. Wright VP, Platt NH (1995) Seasonal wetland carbonate sequences and dynamic catenas: a reappraisal. Sed Geol 99:65–71CrossRefGoogle Scholar
  56. Zaid A, De Wet PF (2002) Chapter II: Origin, geographical distribution and nutritional values of date palm. In: Zaid A, Arias-Jiménez E (eds) Date palm cultivation. FAO Plant Production and Protection Paper 156, Rev. 1, RomeGoogle Scholar

Copyright information

© Springer Science+Business Media Dordrecht 2016

Authors and Affiliations

  • Suparna Goswami
    • 1
  • Elizabeth Gierlowski-Kordesch
    • 2
  • Parthasarathi Ghosh
    • 1
  1. 1.Geological Studies UnitIndian Statistical Institute, KolkataKolkataIndia
  2. 2.Department of Geological SciencesOhio UniversityAthensUSA

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