Stacked Gilbert-type deltas filling an incised palaeovalley along the cratonward margin of a foreland basin (Miocene, Western Carpathian Foredeep)

• Autorzy: Nehyba Slavomír

Identyfikatory

DOI

10.7306/gq.1661

• Języki publikacji: EN

Abstrakty

EN

The coarse-grained Brno sands are an important groundwater aquifer and represent a volumetrically significant component of the Lower Badenian/Middle Miocene sedimentary infill of the Western Carpathian Foredeep, a foreland basin formed on the eastern margin of the Bohemian Massif in front of the Western Carpathians. The integration of core and outcrop facies analysis, summary of facies features, depositional processes and architectures, and integration of provenance analysis have led to a new depositional model for the Brno sands as the product of Gilbert-type delta systems prograding into an incised palaeovalley developed on the outer foreland basin margin. The position, shape and morphology of the palaeovalley were influenced by pre-Neogene basement faults trending NW–SE. The Gilbert-type deltas recognized can be classified as foreset-dominated with other elements subordinate. The foreset beds mainly reflect low-density turbidites, with varied but important evidence of deposits of high-density turbidity currents, cohesionless debris flows and debris falls. The thick foreset deposits show, in detail, repetitive successive prograding-retrograding episodes. These are interpreted as rapid high-frequency pulses of relative sea level change i.e. as high-frequency depositional sequences. The deltaic deposition of the Brno sands was terminated by deposits of a shoal-water delta and the sands were finally drowned by a thick pile of offshore pelagic clays. The provenance of Brno sands is located into the nearby geological units. Redeposition from the older basin infill also played an important role.

Słowa kluczowe

EN

Western Carpathian Foredeep; incised valley; Gilbert-type deltas; stratigraphic architecture; provenance analysis

• Wydawca: Państwowy Instytut Geologiczny - Państwowy Instytut Badawczy
• Czasopismo: Geological Quarterly
• Rocznik: 2022
• Tom: Vol. 66, No. 3
• Strony: art. no. 28
• Opis fizyczny: Bibliogr. 140 poz., fot., rys., tab., wykr.

Twórcy

autor

Nehyba Slavomír

• Depart ment of Geological Sciences, Faculty of Science, Masaryk University, Kotlářská 2, CZ- 611 37 Brno, Czech Republic

Bibliografia

• 1. Adámek, J., 2003. Miocén karpatské předhlubně na jižní Moravě, Geologický vývoj a litostratigrafické členění (in Czech). Zprávy o geologických výzkumech v roce 2002: 9-11.
• 2. Allen, P.A., Burgess, P.M., Galewsky, J., Sinclair, H.D., 2001. Flexural-eustatic numerical model for drowning of the Eocene perialpine carbonate ramp and implications for Alpine geodynamics. GSA Bulletin, 113: 1052-1066.
• 3. Andreucci, S., Panzeri, L., Martini, P., Maspero, F., Martini, M., Pascucci, V., 2014. Evolution and architecture of a West Mediterranean Upper Pleistocene to Holocene coastal Apron-fan system. Sedimentology, 61: 333-361.
• 4. Aubrecht, R., Méres, Š., Sýkora, M., Mikus T., 2009. Provenance of the detrital garnets and spinels from the Albian sediments of the Czorsztyn Unit (Pieniny Klippen Belt, Western Carpathians, Slovakia). Geologica Carpathica, 60: 463-483.
• 5. Backert, N., Ford, M., Malartre, F., 2010. Architecture and sedimentology of the Kerinitis Gilbert-type fan delta, Corinth Rift, Greece. Sedimentology, 57: 543-586.
• 6. Blaško, D., Nehyba, S., 2020. Synchrony evolution of two contradictory prograding Gilbert-type deltas at the margins of the foreland basin (case study from the Neogene Western Carpathian Foredeep). Marine and Petroleum Geology, 118: 1-17.
• 7. Blum, M.D., Törnquist, T.E., 2000. Fluvial responses to climate and sea-level change. A review and look forward. Sedimentology, 47: S1, 2-48.
• 8. Bouma, A.H., 1962. Sedimentology of Some Flysch Deposits: a Graphic Approach to Facies Interpretation. Elsevier, Amsterdam.
• 9. Breda, A., Mellere, D., Massari, F., 2007. Facies and processes in a Gilbert-delta-filled incised valley (Pliocene of Ventimiglia, NW Italy). Sedimentary Geology, 200: 31-55.
• 10. Breda, A., Mellere, D., Massari, F., Asioli, A., 2009. Vertically stacked Gilbert-type deltas of Ventimiglia (NW Italy): the Pliocene record of an overfilled Messinian incised valley. Sedimentary Geology, 219: 58-76.
• 11. Březina, J., Luján, Ŕ.H., Calábková, G., Ivanov, M., 2019. Revision on Historical Finding of the giant Turtle from the Brno Sand (Mliddle Miocene, Lower Badenian). Acta Musei Moraviae, Scientiae Geologicae, 103: 113-128.
• 12. Bridge, J.S., 2003. Rivers and Floodplains. Form, Processes and Sedimentary Record. Blackwell, Oxford.
• 13. Bruhn, R., Steel, R., 2003. High-resolution sequence stratigraphy of a clastic foredeep succession (Paleocene, Spitsbergen): an example of peripheral-bulge controlled depositional architecture. Journal of Sedimentary Research, 73: 745-755.
• 14. Brzobohatý, R., Cicha, I., 1993. Carpatnian Foredeep (in Czech with English summary). In: Geologie Moravy a Slezska (eds. A. Pňchystal, V. Obstová and M. Suk): 123-128, MZM a PřF MU Brno.
• 15. Bubík, M., Petrová, P., 2004. Foraminifera of the Brno Sand in the Černovice TGB-1 borehole (in Czech with English summary). Geologické výzkumy na Moravě a ve Slezsku v roce 2004, 11: 14-17.
• 16. Bubík, M., Nehyba, S., Petrová, P., Pospíšil, O., 2005. Miocene deposits in the HVS-2 borehole in the area of the SAKO a.s. Incinerator Plant in Brno-Líšeň (in Czech with English summary). Geologické výzkumy na Moravě a ve Slezsku v roce 2005, 13: 32-35.
• 17. Bubík, M., Otava, J., Hladilová, Š., 2019. Post-Palaeozoic geological history saved in sedimentary record of Miocene remnants in Brno-Líšeň (in Czech with English summary). Geologické výzkumy na Moravě a ve Slezsku v roce 2019, 26: 16-23.
• 18. Budai, S., Colombera, L., Mountney, N.P., 2021. Quantitative characterization of the sedimentary architecture of Gilbert-type deltas. Sedimentary Geology, 426: 106022.
• 19. Buriánek, D., Tomanová Petrová, P., Otava, J., 2012. Where do the Miocene sediments of the Brno region come from? (in Czech with English summary). Acta Musei Moraviae, Scientiae Geologicae, 97: 153-156.
• 20. Catuneanu, O., Sweet, A.R., 1999. Maastrichtian-Paleocene foreland-basin stratigraphies, western Canada: a reciprocal sequence architecture. Canadian Journal of Earth Sciences, 36: 685-703.
• 21. Catuneanu, O., Willis, A.J., Miall, A.D., 1998. Temporal significance of sequence boundaries. Sedimentary Geology, 121: 157-178.
• 22. Cheel, R.J., Middleton, G.V., 1986. Horizontal lamiane formed under Upper Flow Regime Plane ded conditions. Journal of Geology, 94: 489-504.
• 23. Chlupáč, I, Brzobohatý, R., Kovanda, J., Stráník, Z., 2002. Geologická minulost České republiky (in Czech). Academia, Praha.
• 24. Cogan, J., Lerche, I., Dorman, J.T., Kanes, W., 1993. Flexural plate inversion: application to the Carpathian Foredeep, Czechoslovakia. Modern Geology, 17: 355-392.
• 25. Colella, A., 1988. Pliocene-Holocene fan deltas and braid deltas in the Crati Basin, Southern Italy: a consequence of varying tectonic conditions. In: Fan Deltas (eds. W. Nemec and R.J. Steel): 50-74. Blackie, Glasgow.
• 26. Collinson, J.D., Thompson, D.B., 1982. Sedimentary Structures. Allen and Unwin, London.
• 27. Čopjaková, R., 2007. The reflection of provenance changes in the psefitic and psamitic sedimentary fraction of the Myslejovice Formation (heavy mineral analysis) (in Czech). Ph.D. Thesis, Masaryk University, Brno.
• 28. Čopjaková, R., Sulovský, P., Otava, J., 2002. Comparison of the chemistry of detritic pyrope-almandine garnets of the Lulec Conglomerates with the chemistry of granulite garnets from the Czech Massif (in Czech with English summary). Geologické výzkumy na Moravě a ve Slezku v roce 2001, 9: 44-47.
• 29. Čopjaková, R., Sulovský, P., Paterson, B.A., 2005. Major and trace elements in pyrope-almandine garnets as sediment provenance indicators of the Lower Carboniferous Culm sediments, Drahany Uplands, Bohemian Massif. Lithos, 82: 51-70.
• 30. Dalrymple, R.W., 2004. Incised valleys in time and space: an inroduction to the volume and examination of the controls on valley formation and filling. SEPM Special Publication, 85: 5-12.
• 31. Dietrich, P., Ghienne, J.-F., Normandeau, A., Lajeunesse, P., 2016. Upslope-migrating bedforms in a proglacial sandur delta: cyclic steps from river-derived underflows? Journal of Sedimentary Research, 86: 113-123.
• 32. Dostalíková, L., Valentíková, H., Nehyba, S., 2018. Use of gamma-ray spectrometry for the study of Lower Badenian deposits in the borehole 2241 B Brno-Černá Pole (in Czech with English summary). Geologické výzkumy na Moravě a ve Slezsku v roce 2017, 24: 7-12.
• 33. Edmonds, D.A., Shaw, J.B., Mohrig, D., 2011. Topset-dominated deltas: a new model for river delta stratigraphy. Geology, 39: 1175-1178.
• 34. Eilertsen, R.S., Corner, G.D., Aasheim, O., Hansen, L., 2011. Facies characteristics and architecture related to palaeodepth of Holocene fjord-delta sediments. Sedimentology, 58: 1784-1809.
• 35. Eliáš, M., Pálenský, P., 1998. The model for the development of the Miocene foredeeps in the Ostrava area (in Czech with English summary). Geoscience Research Reports in the year 1997: 65-66.
• 36. Elliott, T., 1989. Deltaic systems and their contribution to an understanding of basin-fill successions. Geological Society Special Publications, 41: 3-10.
• 37. Force, E.R., 1980. The provenance of rutile. Journal of Sedimentary Research, 50: 485-488.
• 38. Francírek, M., Nehyba, S., 2016. Evolution of the passive margin of the peripheral foreland basin: an example from the Lower Miocene Carpathian Foredeep (Czech Republic). Geologica Carpathica, 67: 39-66.
• 39. Galloway, W.E., 1998. Siliciclastic slope and base-of-slope depositional systems: component facies, stratigraphic architecture and classification. AAPG Bulletin, 82: 569-595.
• 40. García-García, F., Fernŕndez, J., Viseras, C., Soria, J.M., 2006. Architecture and sedimentary facies evolution in a delta stack controlled by fault growth (Betic Cordillera, Southern Spain, late Tortonian). Sedimentary Geology, 185: 79-92.
• 41. Gawthorpe, R.L., Colella, A., 1990. Tectonic controls on coarse-grained delta depositional systems in rift basins. IAS Special Publications, 10: 113-127.
• 42. Ghinassi, M., 2007. The effects of differential subsidence and coastal topography on high-order transgressive-regressive cycles: Pliocene nearshore deposits of the Val d'Orcia Basin, Northern Apennines, Italy. Sedimentary Geology, 202: 677-701.
• 43. Gilbert, G.K., 1885. The topographic features of lake shores. U.S. Geological Survey Annual Report, 5: 69-123.
• 44. Gobo, K., Ghinassi, M., Nemec, W., 2014. Reciprocal changes in foreset to bottomset facies in a Gilbert-type delta: response to short-term base level changes: delta brink morphodynamics and related foreset facies. Journal of Sedimentary Research, 84: 1079-1095.
• 45. Gobo, K., Ghinassi, M., Nemec, W., 2015. Gilbert-type deltas recording short-term baselevel changes: delta-brink morphodynamics and related foreset facies. Sedimentology, 62: 1923-1949.
• 46. Gupta, S., 1999. Controls on sedimentation in distal margin pallaeovalleys in the Early Tertiary Alpine foreland basin, south-eastern France. Sedimentology, 46: 357-384.
• 47. Hanžl, P., Krejčí, Z., Vít, J., Otava, J., Novák, Z., Stráník, Z., 1999. Geologická mapa Brna a okolí 1:50 000 (in Czech). Czech Geological Survey.
• 48. Haq, B.U., Hardenbol, J., Vail, P.R., 1988. Mesozoic and Cenozoic chronostratigraphy and cycles of sea-level change. SEPM Special Publication, 42: 71-108.
• 49. Harms, J.C., Southard, J.B., Walker, R.G., 1982. Structures and sequences in clastic rocks. SEPM Short Course, 9.
• 50. Helland-Hansen, W., Gjelberg, J.G., 1994. Conceptual basis and variability in sequence stratigraphy: a different perspective. Sedimentary Geology, 92: 31-52.
• 51. Helland-Hansen, W., Martinsen, O.J., 1996. Shoreline trajectories and sequences: description of variable depositional-dip scenarios. Journal of Sedimentary Research, 66: 670-688.
• 52. Hladilová, Š., Doláková, N., Nehyba, S., Hladíková, J., 2001. New results of the study of Lower Badenian sediments and fossils from some boreholes in the Carpathian Foredeep south of Brno. Geologické výzkumy na Moravě a ve Slezku v roce 2001, 9: 31-34.
• 53. Hohenegger, J., Ćorić, S., Wagreich, M., 2014. Timing of the Middle Miocene Badenian Stage of the Central Paratethys. Geologica Carpathica, 65: 55-66.
• 54. Holcová, K., Doláková, N., Nehyba, S., Vacek, F., 2018. Timing of Langhian bioevents in the Carpathian Foredeep and northern Pannonian Basin in relation to oceanographic, tectonic and climatic processes. Geological Quarterly, 62 (1): 3-17.
• 55. Hubert, J.F., 1962. A zircon-tourmaline-rutile maturity index and the interdependence of the composition of heavy mineral assemblages with the gross composition and texture of sandstones. Journal of Sedimentary Research, 32: 440-450.
• 56. Hwang, I.G., Chough, S.K., 1990. The Miocene Chunbuk formation, southeastern Korea: marine Gilbert-type fan-delta system. IAS Special Publications, 10: 235-254.
• 57. Hwang, I.G., Chough, S.K., Hong, S.W., Chee, M.Y., 1995. Controls on evolution of the fan delta systems in the Miocene Pohang Basin, SE Korea. Sedimentary Geology, 98: 147-179.
• 58. Jervey, M.T., 1988. Quantitative Geological modeling of siliciclastic rock sequences and their seismic expression. SEPM Special Publication, 42: 47-69.
• 59. Jiříček, R., 1987. Stratigraphy and facies subdivision of the deposits of the autochthonous Paleogene on SE slopes of the Bohemian Massif (in Czech). Knihovnička Zemní Plyn a Nafta, 33: 541-567.
• 60. Johnson, H.D., Baldwin, C.T., 1996. Shallow clastic seas. In: SedimentaryEnviroments: Processes, Facies and Stratigraphy (ed. H.G. Reading): 341-353. Blackie, London.
• 61. Kalvoda, J., Bábek, O., Fatka, O., Leichmann, J., Melichar, R., Nehyba, S., Špaček, P., 2008. Brunovistulian terrane (Bohemian Massif, Central Europe) from late Proterozoic to late Paleozoic: a review. International Journal of Earth Sciences, 97: 497-517.
• 62. Kim, J.W., Chough, S.K., 2000. A gravel lobe deposit in the prodelta of the Doumsan fan delta (Miocene), SE Korea. Sedimentary Geology, 130: 183-203.
• 63. Kim, S.B., Chough, S.K., Chun, S.S., 1995. Bouldery deposits in the lowermost part of the Cretaceous Kyokpori Formation, SW Korea: cohesionless debris flows and debris falls on a steep-gradient delta slope. Sedimentary Geology, 98: 97-119.
• 64. Kostic, S., Parker, G., Marr, J.G., 2002. Role of turbidity currents in setting the foreset slope of clinoforms prograding into standing fresh water. Journal of Sedimentary Research, 72: 353-362.
• 65. Kováč, M., Baráth, I., Harzhauser, M., Hlavatý, I., Hudáčková, N., 2004. Miocene depositional systems and sequence stratigraphy of the Vienna basin. Courier Forschunginstitut Senckenberg, 246: 187-212.
• 66. Kováč, M., Grigorovich, A.A., Brzobohatý, R., Fodor, L., Harzhauser, M., Oszczypko, N., Pavelić, D., Rögl, F., Saftić, B., Sliva, L‘., Stráník, Z., 2003. Karpatian paleogeography, tectonics and eustatic changes. In: The Karpatian, A Lower Miocene Stage of the Central Paratethys (eds. R. Brzobohatý, I. Cicha, M. Kováč and F. Rögl): 49-73. Masaryk University, Brno.
• 67. Krejčí, O., Ambrozek, V., Hubatka, F., Tomanová-Petrová, P., Sedlák, J., 2018. Odkrytá strukturní mapa na bázi tercierních sediment hydrogeologického rajonu 2241 a 2242 (in Czech). Czech Geological Survey.
• 68. Krystek, I., 1974. Results of the sedimentological reserch of Lower Badenian deposits in the Carpathian Foredeep (Moravia) (in Czech with English summary). Folia Facultatis Scientiarum Naturalium Universitatis Purkynianae Brunensis, Geologia, 15: 1-32.
• 69. Krystek, I., 1984. Results of the facies and palaeogeographical study of Early Tertiary on the sw. slopes of the Bohemian Massif in segment South (in Czech with English summary). Folia Facultatis Universitatis Purkynianae Brunensis, Geologia, 24: 1-47.
• 70. Krystek, I., Tejkal, J., 1968. Contribution to the lithology and stratigraphy of Miocene of the SW part of the Carpathian Foredeep in Moravia (in Czech with English summary). Folia přírodoěedecké fakulty University J. E. Purkyně v Brně, Geologia, 9: 1-31.
• 71. Krzywiec, P., 2001. Contrasting tectonic and sedimentary history of the central and eastern parts of the Polish Carpathian foredeep basin - results of seismic data interpretation. Marine and Petroleum Geology, 18: 13-38.
• 72. Leszczyński, S., Nemec, W., 2015. Dynamic stratigraphy of composite peripheral unconformity in a foredeep basin. Sedimentology, 62: 645-680.
• 73. Longhitano, S.G., 2008. Sedimentary facies and sequence stratigraphy of coarse-grained Gibert-type deltas within the Pliocene thrust-top Potenza Basin (Southern Apennines, Italy). SedimentaryGeology, 210: 87-110.
• 74. López-Blanco, M., Marzo, M., Piña, J., 2000. Transgressive-regressive sequence hierarchy of foreland, fan-delta clastic wedges (Montserrat and Sant Llorenç del Munt, Middle Eocene, Ebro Basin, NE Spain). Sedimentary Geology, 138: 41-69.
• 75. Lowe, D.R., 1982. Sediment gravity flows: II. Depositional models with special reference to the depos its of high-density turbidity currents. Journal of Sedimentary Petrology, 52: 279-297.
• 76. Mange, M.A., Morton, A.C., 2007. Geochemistry of heavy minerals. In: Heavy Minerals in Use. Developments in Sedimentology, 58: 345-391.
• 77. Martini, I., Ambrosetti, E., Sandrelli, F., 2017. The role of sediment supply in large-scale stratigraphic architecture of ancient Gilbert-type deltas (Pliocene Siena-Radicofani Basin, Italy). Sedimentary Geology, 350: 23-41.
• 78. Massari, F., 1996. Upper-flow-regime stratification types on steep-face, coarse-grained, Gilbert-type progradational wedges (Pleistocene, southern Italy). Journal of Sedimentary Research, 66: 364-375.
• 79. Massari, F., Colella, A., 1988. Evolution and types of fan-delta systems in some major tectonic setting. In: Fan Deltas (eds. W. Nemec and R.J. Steel): 101-122. Blackie and Son, London.
• 80. Massari, F., Parea, G.C., 1990. Wave-dominated Gilbert-type gravel deltas in the hinterland of the Gulf of Taranto (Pleistocene, southern Italy). IAS Special Publications, 10: 311-331.
• 81. Meinhold, G., Anders, B., Kostopoulos, D., Reischmann, T., 2008. Rutile chemistry and thermometry as provenance indicator: an example from Chios Island, Greece. Sedimentary Geology, 203: 98-111.
• 82. Miall, A.D., 1996. Principles of Sedimentary Basin Analysis. Springer, New York.
• 83. Miller, K.G., Mountain, G.S., Browning, J.V., Kominz, M., Sugarman, P.J., Christie-Blick, N., Katz, M.E., Wright, J.D., 1998. Cenozoic global sea level, sequences, and the New Jersey Transect: results from coastal plain and continental slope drilling. Reviews of Geophysics, 36: 569-601.
• 84. Mortimer, E., Gupta, S., Cowie, P., 2005. Clinoform nucleation and growth in coarse grained deltas, Loreto basin, Baja California Sur, Mexico: a response to episodic accelerations in fault displacement. Basin Research, 17: 337-359.
• 85. Morton, A.C., 1984. Stability of detrital heavy minerals in Tertiary sandstones from the North Sea Basin. Clay Minerals, 19: 287-308.
• 86. Morton, A.C., Hallsworth, C.R., 1994. Identifying provenance-specific features of detrital heavy mineral assemblages in sandstones. Sedimentary Geology, 90: 241-256.
• 87. Mulder, T., Alexander, J., 2001. The physical character of subaqueous sedimentary density flows and their deposits. Sedimentology, 48: 269-299.
• 88. Muto, T., Steel, R.J., 1997. Principles of regression and transgression: the nature of the interplay between accommodation and sediment supply. Journal of Sedimentary Research, 67: 994-1000.
• 89. Nehyba, S., 2018. Lower Badenian coarse-grained Gilbert deltas in the southern margin of the Western Carpathian Foredeep basin. Geologica Carpathica, 69: 89-113.
• 90. Nehyba, S., Roetzel, R., 2010. Fluvial deposits of the St. Marein-Freischling Formation - insights into initial depositional processes on the distal external margin of the Alpine-Carpathian Foredeep in Lower Austria. Austrian Journal of Earth Sciences, 103: 50-80.
• 91. Nehyba, S., Šikula, J., 2007. Depositional architecture, sequence stratigraphy and geodynamic development of the Carpathian Foredeep (Czech Republic). Geologica Carpathica, 58: 53-69.
• 92. Nehyba, S., Roetzel, R., Adamová, M., 1999. Tephrostratigraphy of the Neogene volcaniclastics (Moravia, Lower Austria, Poland). Geologica Carpathica, 50 (Spec. Iss.): 126-128.
• 93. Nehyba, S., Tomanová Petrová, P., Zágoršek, K., 2008. Sedimentological and palaeocological records of the evolution of the south-western part of the Carpathian Foredeep (Czech Republic) during the Early Badenian. Geological Quarterly, 52 (1): 45-60.
• 94. Nehyba, S., Holcová, K., Gedl, P., Doláková, N., 2016. The Lower Badenian transgressive-regressive cycles - a case study from Oslavany (Carpathian Foredeep, Czech Republic). Neues Jahrbuch für Geologie und Paläontologie - abhandlungen, 279: 209-238.
• 95. Nehyba, S., Gilíková, H., Tomanová-Petrová, P., Otava, J., Skácelová, Z., 2019. Evolution of a sedimentary infill of a palaeovalley at a distal margin of the peripheral foreland basin. Geological Quarterly, 63 (2): 319-344.
• 96. Nemec, W., 1990. Aspects of sediment movement on steep delta slope. IAS Special Publications, 10: 29-73.
• 97. Nemec, W., 1995. The dynamics of deltaic suspension plumes. In: Geology of Deltas (eds. M.N. Oti and G. Postma): 31-93. Balkema, Rotterdam, NT.
• 98. Nemec, W., Steel, R.J., Porebski, S.J., Spinnangr, A., 1984. Domba conglomerate, Devonian, Norway: process and lateral variability in a mass flow-dominated, lacustrine fandelta. Canadian Society of Petroleum Geologists Memoir, 10: 295-320.
• 99. Nemec, W., Lǿnne, I., Blikra, L.H., 1999. The Kregnes moraine in Gauldalen, west-central Norway: anatomy of a Younger Dryas proglacial delta in a palaeofjord basin. Boreas, 28: 454-476.
• 100. Okazaki, H., Isaji, S., Kurozumi, T., 2020. Sedimentary facies related to supercritical-flow bedforms in foreset slopes of a Gilbert-type delta (middle Peistocene, central Japan). Sedimentary Geology, 399.
• 101. Oszczypko, N., Krzywiec, P., Popadyuk, I., Peryt, T., 2006. Carpathian Foredeep Basin (Polish and Ukraine): its sedimentary, structural, and geodynamic evolution. AAPG Memoir, 84: 293-350.
• 102. Otava, J., Sulovský, P., Čopjaková, R., 2000. Provenance changes of the Drahany Culm greywackes: statistical evaluation. (in Czech), Geologické výzkumy na Moravě a ve Slezku v roce 1999: 94-98.
• 103. Papp, A., Cicha, I., Seneš, J., Steininger, F., 1978. Chronostratigraphie und neostratotypen, Miozän der Zentralen Paratethys, 4, M4 Badenian (Moravien, Wielicien, Kosovien). Bratislava (Veda).
• 104. Petrová, P., 2004. Foraminiferal assemblages as an indicator of foreland basin evolution (Carpathian Foredeep, Czech Republic). Bulletin of Geosciences, 79: 231-242.
• 105. Pícha, F.J., 1979. Ancient submarine canyons of Tethyan continental margins, Czechoslovakia. AAPG Bulletin, 63: 67-86.
• 106. Pícha, F.J., Stránik, Z., Krejčí, O., 2006. Geology and hydrocarbon resources of the Outer Western Carpathians and their foreland, Czech Republic. AAPG Memoir, 84: 49-175.
• 107. Plink-Björklund, P., Ronnert, L., 1999. Depositional processes and internal architecture of Late Weichselian ice-margin submarine fan and delta settings, Swedish west coast. Sedimentology, 46: 215-234.
• 108. Postma, G., 1984. Mass-flow conglomerates in a submarine canyon: abrioja fan delta, Pliocene, Southeast Spain. Canadian Society of Petroleum Geologists Memoir, 10: 237-258.
• 109. Postma, G., 2001. Physical climate signatures in shallow and deep-water deltas. Global and Planetary Change, 28: 93-106.
• 110. Postma, G., Cruickshank, C., 1988. Sedimentology of a late Weichselian to Holocene, terraced fan delta, Varangerfjord, northern Norway. In: Fan Deltas (eds. W. Nemec and R.J. Steel): 144-157. Blackie and Son.
• 111. Poulimenos, G., Zelilidis, A., Kontopoulos, N., Doutsos, T., 1993. Geometryof trapezoidal fan deltas and their relationship to extensional faulting along the southwestern active margins of the Corinth rift, Greece. Basin Research, 5: 179-192.
• 112. Powers, M.C., 1982. Comparison chart for estimating roundness and sphericity. AGI Data Sheet 18.
• 113. Rasmussen, H., 2000. Nearshore and alluvial facies in the Sant Llorenç del Muntdepositional system: recognition and development. Sedimentary Geology, 138: 71-98.
• 114. Rubi, R., Rohais, S., Bourquin, S., Moretti, I., Desaubliaux, G., 2018. Processes and typology in Gilbert-type delta bottomset deposits based on outcrop examples in the Corinth Rift. Marine and Petroleum Geology, 92: 193-212.
• 115. Russell, A.J., 2007. Controls on the sedimentology of an ice-contact jökulhlaup-dominated delta, Kangerlunssuaq, west Greenland. Sedimentary Geology, 193: 137-148.
• 116. Shanley, K.W., McCabe, P.J., 1994. Perspectives on the sequence stratigraphy of continental strata. AAPG Bulletin, 78: 544-568.
• 117. Smith, N.D., 1974. Sedimentology and bar formation in the upper Kicking Horse River, a braided outwash stream. Journal of Geology, 81: 205-223.
• 118. Sohn, Y.K., Kim, S.B., Hwang, I.G., Choe, M.Y., Chough, S.K., 1997. Characteristic and depositional processes of large-scale gravelly Gilbert-type foresets in the Miocene Doumsan fan delta, Pohang basin, SE Korea. Journal of Sedimentary Research, 67: 130-141.
• 119. Steel, R.J., Olsen, T., 2002. Clinoforms, clinoform trajectories and deepwater sands. GCS-SEPM Special Publication: 367-361.
• 120. Talling, P.J., Masson, D.G., Sumner, E.J., Malgesini, G., 2012. Subaqueous sediment density flows: depositional processes and deposit types. Sedimentology, 59: 1937-2003.
• 121. Tolosana-Delgado, R., von Eynatten, H., Krippner, A., Meinhold, G., 2018. A multivariate discrimination scheme of detrital garnet chemistry for use in sediment provenance analysis. Sedimentary Geology, 375: 14-26.
• 122. Tomanová-Petrová, P., Švábebnická, L., 2007. Lower Badenian biostratigraphy and paleoecology: a case study from the Carpathian Foredeep (Czech Republic). Geologica Carpathica, 58: 333-352.
• 123. Triebold, S., Eynatten, H. von, Luvizotto, G.L., Zack, T., 2007. Deducing source rock lithology from detrital rutile geochemistry: an example from the Erzgebirge, Germany. Chemical Geology, 244: 421-436.
• 124. Triebold, S., Eynatten H. von, Zack, T., 2012. A recipe for the use of rutile in sedimentary provenance analysis. Sedimentary Geology, 282: 268-275.
• 125. Tucker, M. 1995. Techniques in Sedimentology. Blackwell Science, Oxford.
• 126. Turmel, D., Locat, J., Parker, G., 2015. Morphological evolution of a well-constrained, subaerial-subaqueous source to sink system: Wabush Lake. Sedimentology, 62: 1636-1664.
• 127. Ventra, D., Cartigny, M.J.B., Bijkerk, J.F., Acikalin, S., 2015. Supercritical-flow structures on a Late Carboniferous delta front: sedimentological and paleoclimatic significance. Geology, 43: 731-734.
• 128. Viparelli, E., Blom, A., Parker, G., 2012. Modeling stratigraphy formed by prograding Gilbert deltas. In: River Flow 2012 (ed. E. Murillo): 827-836. Taylor and Francis Group, London.
• 129. Viseras, C., Calvache, M.L., Soria, J.M., Fernandez, J., 2003. Differential features of alluvial fans controlled by tectonic or eustatic accommodation space. Examples from the Betic Cordillera, Spain. Geomorphology, 50: 181-202.
• 130. Walker, R.G., James, N.P., 1992. Facies Models: Response to Sea Level Changes. Geological Association of Canada, St. John's.
• 131. Wang, R., Colombera, L., Mountney, N.P., 2019. Geologic controls on the geometry of incised-valley fills:Insights from a global dataset of late-Quaternary examples. Sedimentology, 66: 2134-2168.
• 132. Waschbusch, P.J., Royden, L.H., 1992. Spatial and temporal evolution of foredeep basins: lateral strength variations and inelastic yielding in continental lithoshere. Basin Research, 4: 179-196.
• 133. Watson, E., Wark, D., Thomas, J., 2006.Crystallization thermometers for zircon and rutile. Contributions to Mineralogy and Petrology, 151: 413-433.
• 134. Weleschuk, Z.P., Dashtgard, S.E., 2019. Evolution of an ancient (Lower Cretaceous) marginal-marine system from tide-dominated to wave-dominated deposition, McMurray Formation. Sedimentology,66: 2354-2391.
• 135. Zack, T., Eynatten, H. von, Kronz, A., 2004a. Rutile geochemistry and its potential use in quantitative provenance studies. Sedimentary Geology, 171: 37-58.
• 136. Zack, T., Moraes, R., Kronz, A., 2004b.Temperature dependence of Zr in rutile: empirical calibration of a rutile thermometer. Contributions to Mineralogy and Petrology, 148: 471-488.
• 137. Zaitlin, B.A., Dalrymple, R.W., Boyd, R., 1994. The stratigraphic organization of incised-valley systems associated with relative sea-level change. SEPM Special Publication, 51: 45-60.
• 138. Zavala, C., Arcuri, M., 2016. Intrabasinal and Extrabasinal turbidites: origin and distinctive characteristics. Sedimentary Geology, 337: 36-54.
• 139. Zelilidis, A., Kontopoulos, N., 1996. Significance of fan deltas without toe-sets within rift and piggy-back basins: examples from the Corinth graben and the mesohellenic trough, Central Greece. Sedimentology, 43: 253-262.
• 140. Zingg, T., 1935. Beitrag zur Schotteranalyse. Die Schotteranalyse und ihre Anwendung auf die Glattalschotter. Schweizerische Mineralogische und Petrographische Mitteilungen, 15: 39-140.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).