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Tytuł artykułu

Fluid pathways within shallow-generated damage zones of strike-slip faults – evidence of map-scale faulting in a continental environment, SW Permo-Mesozoic cover of the Late Palaeozoic Holy Cross Mountains Fold Belt, Poland

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Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The damage zones of exhumed strike-slip faults dissecting Jurassic carbonates in the south-western part of the Late Palaeozoic Holy Cross Mountains Fold Belt reveal second-order faults and fractures infilled with syntectonic calcite. The subsequent development of a structural pattern of microscopic fault-related structures and calcite infillings reflects the activity of strike-slip faults that began in the Late Cretaceous (Late Maastrichtian) and lasted until the early Miocene (Langhian). The fabric of the syntectonic veins provides insights into the evolution of the permeable fault-related structures that were the main pathways for fluid flow during fault activity. Microstructural study of calcite veins coupled with stable isotope and fluid inclusion data indicates that calcite precipitated primarily in a rock-buffered system related to strike-slip fault movement, and secondarily in a partly open system related to the local activity of the releasing Chmielnik stepover or the uplift of the area. The presence of meteoric fluids descending from the surface into damage zones suggest that the strike-slip faulting might have taken place in a nonmarine, continental environment.
Rocznik
Strony
1--29
Opis fizyczny
Bibliogr. 163 poz., rys., tab.
Twórcy
  • University of Warsaw, Faculty of Geology, Żwirki i Wigury 93, 02-089 Warsaw, Poland
  • University of Warsaw, Faculty of Geology, Żwirki i Wigury 93, 02-089 Warsaw, Poland
  • Slovak Academy of Sciences, Earth Science Institute, Dúbravská cesta 9, 840 05 Bratislava, Slovakia
  • Polish Academy of Sciences, Institute of Geological Sciences, Twarda 51/55, 00-818 Warsaw, Poland
  • Polish Geological Institute – National Research Institute, Rakowiecka 4, 00-975 Warsaw, Poland
  • University of Warsaw, Faculty of Geology, Żwirki i Wigury 93, 02-089 Warsaw, Poland
Bibliografia
  • 1. Agosta, F. and Aydin, A. 2006. Architecture and deformation mechanism of a basin-bounding normal fault in Mesozoic platform carbonates, central Italy. Journal of Structural Geology, 28, 1445-1467.
  • 2. Agosta, F. and Kirschner, D.L. 2003. Fluid conduits in carbonate-hosted seismogenic normal faults of Central Italy. Journal of Geophysical Research, 108, B4 2221, 1-13.
  • 3. Ahlgren, S.G. 2001. The nucleation and evolution of Riedel shear zones as deformation bands in porous sandstone. Journal of Structural Geology, 23, 1203-1214.
  • 4. Alexandrowicz, S.W., Garlicki, A. and Rutkowski, J. 1982. Podstawowe jednostki litostratygraficzne miocenu zapad liska przedkarpackiego. Kwartalnik Geologiczny, 26, 470-471.
  • 5. Arndt, M., Virgo, S., Cox, S.F. and Urai, J.L. 2014. Changes in fluid patways in calcite vein mesh (Natih Formation, Oman Mountains): insights from stable isotopes. Geofluids, 1-28. DOI 10.1111/gfl.12083
  • 6. Bada, G. 1999. Cenozoic stress field evolution in the Pannonian basin and surrounding orogens. Inferences from kinematic indicators and finite element modelling, 205 p. Vrije Universiteit Amsterdam, Amsterdam.
  • 7. Bartlett, W.L., Friedman, M. and Logan, J.M. 1981 Experimental folding and faulting of rocks under confining pressure. Tectonophysics, 79, 255-277.
  • 8. Ben-Avraham, Z. 1985. Structural framework of the Gulf of Elat (Aqaba), northern Red Sea. Journal of Geophysical Research, 90, 703-726.
  • 9. Billi, A., Salvini, F. and Storti, F. 2003. The damage zone-fault core transition in carbonate rocks: implications for fault growth structure and permeability. Journal of Structural Geology, 25, 1779-1794.
  • 10. Bons, P.D., Elburg, M.A. and Gomez-Rivas, E. 2012. A review of the formation of tectonic veins and their microstructures. Journal of Structural Geology, 43, 33-62.
  • 11. Brogi, A. 2008. Fault zone architecture and permeability features in siliceous sedimentary rocks: Insights from the Rapolano geothermal area (Northern Apennines, Italy). Journal of Structural Geology, 30, 237-256.
  • 12. Caine, .JS., Evans, J.P. and Forster, C.B. 1996. Fault zone architecture and permeability structure. Geology, 24, 1025-1028.
  • 13. Caine, J.S. and Forster, C.B. 1999. Fault zone architecture and fluid flow; insights from field data and numerical modelling. In: Haneberg, W.C., Mozley, P.S., Moore, J.C. and Goodwin, L.B. (Eds), Faults and Sub-surface Fluid Flow in the Shallow Crust. AGU Geophysical Monograph, 113, 101-127.
  • 14. Caine, J.S., Bruhn, R.L. and Forster, C.B. 2010. Internal structure fault rocks and inferences regarding deformation fluid flow and mineralization in the seismogenic Stillwater normal fault, Dixie Valley Nevada. Journal of Structural Geology, 32, 1576-1589.
  • 15. Cao, S. and Neubauer, F. 2016. Deep crustal expressions of exhumed strike-slip fault systems: Shear zone initiation on rheological boundaries. Earth-Science Reviews, 162, 155-176.
  • 16. Chester, F.M. and Logan, J.M. 1986. Implications for mechanical-properties of brittle faults from observations of the Punch bowl fault zone, California. Pure Applied Geophysics, 124, 79-106.
  • 17. Chester, F.M., Evans, J.P. and Biegel, R.L. 1993. Internal structure and weakening mechanism of the S.Andreas Fault. Journal of Geophysical Research, 98, 771-786.
  • 18. Cieśla, E. and Lindner, L. 1990. Geological Map of Poland. Końskie sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 19. Cohen, K., Finney, S., Gibbard, P. and Fan, J.-X. 2013. The ICS international chronostratigraphic chart. Episodes, 36, 199-204.
  • 20. Cox, S.F. 2007. Structural and isotopic constraints on fluid flow regimes and fluid pathways during upper crustal deformation: An example from the Taemas area of the Lachlan Orogen, SE Australia. Journal of Geophysical Research, 112, B08208, 1-23.
  • 21. Crider, J.G. and Peacock, D.C.P. 2004. Initiation of brittle faults in the upper crust: A review of field observations. Journal of Structural Geology, 26, 691-707.
  • 22. Czarnocki, J. 1938. Carte geologique generale de la Pologne, feuille 4, Kielce, scale 1:100 000. Edition du Service Geologique de Pologne; Warszawa.
  • 23. Czarnocki, J. 1961. Materiały do przeglądowej mapy geologicznej Polski. Region Świętokrzyski. Arkusz Kielce, scale 1:100 000. Wydanie B zaktualizowane. Wydawnictwa Geologiczne; Warszawa.
  • 24. Dadlez, R. and Marek, S. 1997. Tektonika kompleksu permsko- mezozoicznego. Prace Państwowego Instytutu Geo logicznego, 153, 410-415.
  • 25. Dadlez, R., Marek, S. and Pokorski, J. 1998. Atlas paleogeograficzny epikontynentalnego permu i mezozoiku w Polsce. Wydawnictwo Kartograficzne Polskiej Agencji Eko logicznej; Warszawa.
  • 26. Dadlez, R. 2003. Mesozoic thickness pattern in the Mid-Polish Trough. Geological Quarterly, 47, 223-240.
  • 27. Dadlez, R., Jóźwiak, W. and Młynarski, S. 1997. Subsidence and inversion in the western part of Polish basin - data from aseismic velocities. Geological Quarterly, 41, 197-208.
  • 28. Doblas, M., Manecha, V., Hoyos, M. and Lopez-Ruiz, J. 1997. Slickenside and fault surface kinematic indicators on active normal faults of the Alpine Betic Cordilleras, Granada, southern Spain. Journal of Structural Geology, 19, 159-170.
  • 29. Durney, D.W. and Ramsay, J.G. 1973. Incremental strains measured by syntectonic crystal growths. In: De Jong, K.A. and Scholten, K. (Eds), Gravity and Tectonics, pp. 67-96. John Wiley & Sons; New York.
  • 30. Ebner, M., Piazolo, S., Renard, F. and Koehn, D. 2010. Stylolite interfaces and surrounding matrix material: Nature and role of heterogeneities in roughness and microstructural development. Journal of Structural Geology, 32, 1070-1084.
  • 31. Engelder, T. 1999. Transitional-tensile fracture propagation: a status report. Journal of Structural Geology, 21, 1049-1055.
  • 32. Faulkner, D.R., Jackson, C.A.L., Lunn, R.J., Schlische, R.W., Shipton, Z.K., Wibberley, C.A.J. and Withjack, M.O. 2010. A review of recent developments concerning the structure mechanics and fluid flow properties of fault zones. Journal of Structural Geology, 32, 1557-1575.
  • 33. Faulkner, D.R., Lewis, A.C. and Rutter, E.H. 2003. On internal structure and mechanics of large strike-slip fault zones: field observations of the Carboneras fault in southern Spain. Tectonophysics, 367, 235-251.
  • 34. Filonowicz, P. 1967. Geological Map of Poland, Morawica sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 35. Filonowicz, P. and Lindner, L. 1986. Geological Map of Poland, Piekoszów sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 36. Finzi, Y., Hearn, E.H., Ben-Zion, Y. and Lyakhovsky, V. 2009. Structural properties and deformation patterns of evolving strike-slip faults: Numerical simulations incorporating damage rheology. Pure Applied Geophysics, 166, 1537- 1573.
  • 37. Fitz-Diaz, E., Hudleston, P., Sebenaller, L., Kirschner, D., Camprubí, A., Tolson, G. and Puig, P.T. 2011. Insights into fluid flow and water-rock interaction during deformation of carbonate sequences in the Mexican fold-thrust belt. Journal of Structural Geology, 33, 1237-1253.
  • 38. Gągała, Ł., Vergés, J., Saura, E., Malata, T., Ringenbach, J.-C., Werner, P. and Krzywiec, P. 2012. Architecture and orogenic evolution of the northeastern Outer Carpathians from cross-section balancing and forward modeling. Tectonophysics, 532, 223-241.
  • 39. Golonka, J., Krobicki, M., Oszczypko, N., Ślączka, A. and Słomka, T. 2003. Geodynamic evolution and palaeogeography of the Polish Carpathians and adjacent areas during Neo-Cimmerian and preceding events (latest Triassic-earliest Cretaceous). Geological Society Special Publications, 208, 137-158.
  • 40. Golonka, J., Oszczypko, N. and Ślączka, A. 2000. Late Carboniferous-Neogene geodynamic evolution and palaeogeography of the circum-Carpathian region and adjacent areas. Annales Societatis Geologorum Poloniae, 70, 107-136.
  • 41. Górka, M.J. 2015. Kenozoiczna ewolucja świętokrzyskiego brzegu Paratetydy. Geologia wschodniego Ponidzia. In: Skompski, S. (Ed.), Ekstensja i inwersja powaryscyjskich basenów sedymentacyjnych. LXXXIV Zjazd Naukowy Polskiego Towarzystwa Geologicznego Chęciny, 9-11 września 2015 r., Sesja terenowa II, 138-144. Państwowy Instytut Geologiczny, Państwowy Instytut Badawczy; Warszawa.
  • 42. Gradziński, M., Duliński, M., Hercman, H., Górny, A. and Przybyszowski, S. 2012. Peculiar calcite speleothems filling fissures in calcareous sandstones and their palaeohydrological and palaeoclimatic significance: an example from the Polish Carpathians. Geological Quarterly, 56, 711-732.
  • 43. Gratier, J.P., Dysthe, D. and Renard, F. 2013. The Role of Pressure Solution Creep in the Ductility of the Earth’s Upper Crust. Advances in Geophysics, 54, 47-179.
  • 44. Gratier, J.-P., Favreau, P. and Renard, F. 2003. Modelling fluid transfer along California faults when integrating pressure solution crack sealing and compaction processes. Journal of Geophysical Research, 108 (B2), 28-52.
  • 45. Gratier, J.-P., Frery, E., Deschamps, P., Røyne, A., Renard, F., Dysthe, D., Ellouz-Zimmerman, N. and Hamelin, B. 2009. How travertine veins grow from top to bottom and lift the rocks above them: The effect of crystallization force. Geology, 40, 1015-1018.
  • 46. Gratier, J.P., Richard, J., Renard, F., Mittempergher, S., Doan, M.L., Di Toro, G., Hadizadeh, J. and Boullier, A.M. 2011. Aseismic sliding of active faults by pressure solution creep: Evidence from the San Andreas Fault Observatory at Depth. Geology, 39, 1131-1134.
  • 47. Gruszczyński, M. and Mastella, L. 1986. Calcareous tufas in the area of the Mszana Dolna tectonic window. Annales Societatis Geologorum Poloniae, 56, 117-131. [In Polish with English summary]
  • 48. Grzybowski, K. and Kutek, J. 1967. Geological Map of Poland, Lubień sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 49. Gutowski, J. and Koyi, H. 2007. Influence of oblique basement strike-slip faults on the Mesozoic evolution of the south-eastern segment of the Mid-Polish Trough. Basin Research, 19, 67-86.
  • 50. Hakenberg, M. 1969. Albian and Cenomanian between Małogoszcz and Staniewice, SW border of the Holy Cross Mountains. Studia Geologica Polonica, 26, 1-126. [In Polish with English summary]
  • 51. Hakenberg, M. 1973. Geological Map of Poland, Chęciny sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 52. Hakenberg, M. and Świdrowska J., 2001. Cretaceous basin evolution in the Lublin area along the Teisseyre-Tornquist Zone (SE Poland). Annales Societatis Geologorum Poloniae, 71, 1-20.
  • 53. Hakenberg, M. and Świdrowska, J. 1998. Rozwój południowo - wschodniego segmentu bruzdy polskiej i jego związek ze strefami uskoków ograniczających (od permu do późnej jury). Przegląd Geologiczny, 46, 503.
  • 54. Hancock, P.L., Chalmers, R.M.L., Altunel, E. and Çakir, Z. 1999. Travitonics: using travertines in active fault studies. Journal of Structural Geology, 21, 903-916.
  • 55. Heap, M.J., Baud, P., Reuschlé, T. and Meredith, P.G. 2014. Stylolites in limestones: Barriers to fluid flow? Geology, 42, 51-54.
  • 56. Heap, M.J., Reuschlé, T., Baud, P., Renard, F. and Iezzi, G. 2018. The permeability of stylolite-bearing limestone. Journal of Structural Geology, 116, 81-93.
  • 57. Hohenegger, J., Ćorić, S. and Wagreich, M. 2014. Timing of the middle miocene Badenian stage of the central Paratethys. Geologica Carpathica, 65, 55-66.
  • 58. Irwin, H., Curtis, C., and Coleman, M. 1977. Isotopic evidence for source of diagenetic carbonates formed during burial of organic-rich sediments. Nature, 269, 209-213.
  • 59. Janiec, J. 1991. Geological Map of Poland. Żarnów sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 60. Jarosiński, M. 1992. The tectonics of the argillaceous rocks of the cover of the sulphur deposit in Machow near Tarnobrzeg in the light of the mesostructural analysis. Geological Quarterly, 36, 121-150. [In Polish with English summary]
  • 61. Jarosiński, M., Poprawa, P. and Ziegler, P.A. 2009. Cenozoic dynamic evolution of the Polish Platform. Geological Quarterly, 53, 3-26.
  • 62. Jurkiewicz, I. 1961. Materiały do przeglądowej mapy geologicznej Polski. Region Świętokrzyski, arkusz Przedbórz. Wydanie B zaktualizowane, skala 1:100,000. Wydawnictwa Geologiczne; Warszawa.
  • 63. Jurkiewicz, I. 1965. Geological Map of Poland, Czermno sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 64. Jurkiewicz, I. 1967. Geological Map of Poland, Radoszyce sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 65. Kenis, I., Muchez, P.H., Sintubin, M., Mansy, J.L. and Lacquement, F. 2000. The use of a combined structural, stable isotope and fluid inclusion study to constrain the kinematic history at the northern Variscan front zone (Bettrechies, northern France). Journal of Structural Geology, 22, 589- 602.
  • 66. Kim, S.T., Mucci, A. and Taylor, B.E. 2007. Phosphoric acid fractionation factors for calcite and aragonite between 25 and 75°C: Revisited. Chemical Geology, 246, 135-146.
  • 67. Kim, Y.-S. and Sanderson, D.J. 2010. Inferred fluid flow through fault damage zones based on the observation of stalactites in carbonate caves. Journal of Structural Geology, 32, 1305- 1316.
  • 68. Kim, Y.-S., Peacock, D.C.P. and Sanderson, D.J. 2003. Strikeslip faults and damage zones at Marsalforn, Gozo Island, Malta. Journal of Structural Geology, 25, 793-812.
  • 69. Knipe, R.J. 1993. The influence of fault zone processes and diagenesis on fluid flow. In: Horbury, A.D. and Robinson, A. (Eds), Diagenesis and Basin Development. Association of Petroleum Geologists Studies in Geology, 36, 35-51.
  • 70. Koehn, D., Renard, F., Toussaint, R. and Passchier, C.W. 2007. Growth of stylolite teeth patterns depending on normal stress and finite compaction. Earth and Planetary Letters, 257, 582-595.
  • 71. Konon, A. 2007. Strike-slip faulting in the Kielce Unit, Holy Cross Mountains, central Poland. Acta Geologica Polonica, 57, 415-441.
  • 72. Konon, A. 2015. Przejawy przesuwczości w obrębie południowo-zachodniego obrzeżenia permsko-mezozoicznego Gór Świętokrzyskich. LXXXIV Zjazd Naukowy Polskiego Towarzystwa Geologicznego, Chęciny, 9-11 września 2015, Ekstensja i inwersja powaryscyjskich basenów sedymentacyjnych, pp. 59-67. Państwowy Instytut Geologiczny, Państwowy Instytut Badawczy; Warszawa
  • 73. Konon, A., Ostrowski, S., Rybak-Ostrowska, B., Ludwiniak, M., Śmigielski, M., Wyglądała, M., Uroda, J., Kowalczyk, S., Mieszkowski, R. and Kłopotowska, A. 2016. Mnin restraining stepover - evidence of significant Cretaceous-Cenozoic dextral strike-slip faulting along the Teisseyre- Tornquist Zone? Acta Geologica Polonica, 66, 435-455.
  • 74. Konon. A and Mastella, L. 2001. Structural evolution of the Gnieździska Syncline - regional implications for the SW Mesozoic Margin of the Holy Cross Mountains (Central Poland). Annales Societatis Geologorum Poloniae, 71, 189-199.
  • 75. Kováč, M., Nagymarosy, A., Soták, J. and Šutovská, K. 1993. Late Tertiary paleogeographic evolution of the Western Carpathians. Tectonophysics, 226, 401-415.
  • 76. Krajewski, R. 1961. Materiały do Przeglądowej mapy geologicznej Polski. Region Świętokrzyski, arkusz Końskie, skala 1:100 000. Wydanie B zaktualizowane. Wydawnictwa Geologiczne; Warszawa.
  • 77. Krzywiec, P. 2000. O mechanizmach inwersji bruzdy środkowo polskiej - wyniki interpretacji danych sejsmicznych. Biuletyn Państwowego Instytutu Geologicznego, 393, 135-166.
  • 78. Krzywiec, P. 2002. Mid-Polish Trough inversion - seismic examples, main mechanisms and its relationship to the Alpine-Carpathian collision. EGU Stephan Mueller Special Publication Series, 1, 151-165.
  • 79. Krzywiec, P. 2006. Structural inversion of the Pomeranian and Kuiavian segments of the Mid-Polish Trough-lateral variations in timing and structural style. Geological Quarterly, 50, 151-168.
  • 80. Krzywiec, P. 2007. Tectonics of the Lublin area (SE Poland) - new views based on results of seismic data interpretation. Biuletyn Państwowego Instytutu Geologicznego, 422, 1-18. [In Polish]
  • 81. Krzywiec, P. 2009. Devonian-Cretaceous repeated subsidence and uplift along the Teisseyre-Tornquist zone in SE Poland—Insight from seismic data interpretation. Tectonophysics, 475, 142-159.
  • 82. Krzywiec, P., Gutowski, J., Walaszczyk, I., Wróbel, G. and Wybraniec, S. 2009. Tectonostratygraphic model of the Late Cretaceous inversion along the Nowe Miasto-Zawichost fault zone, SE Mid-Polish Trough. Geological Quarterly, 53, 27-48.
  • 83. Krzywiec, P., Oszczypko, N., Bukowski, K., Oszczypko-Clowes, M., Śmigielski, M., Stuart, F.M., Persano, C. and Sinclair, H.D. 2014. Structure and evolution of the Carpathian thrust front between Tarnów and Pilzno (Pogórska Wola area, southern Poland) - results of integrated analysis of seismic and well data. Geological Quarterly, 58, 409-426.
  • 84. Krzywiec, P., Stachowska, A. and Stypa, A. 2018. The only way is up-on Mesozoic uplifts and basin inversion events in SE Poland. Geological Society, London, Special Publications, 469, SP469-14.
  • 85. Kuleta, M. and Zbroja, S. 2006. Wczesny etap rozwoju pokrywy permsko-mezozoicznej w Górach Świętokrzyskich. In: Skompski, S. and Żylińska, A. (Eds), 77 Zjazd Naukowy Polskiego Towarzystwa Geologicznego, Ameliówka k. Kielc, 28-30 czerwca 2006 r., Materiały konferencyjne, pp. 105-125. Państwowy Instytut Geologiczny; Warszawa.
  • 86. Kutek, J. and Głazek, J. 1972. The Holy Cross area, central Poland, in the Alpine cycle. Acta Geologica Polonica, 22, 603-651.
  • 87. Kutek, J. 1968. The Kimmeridgian and Uppermost Oxfordian in the SW margin of the Holy Cross Mts, Central Poland. Part I. Stratigraphy. Acta Geologica Polonica, 18, 493- 586. [In Polish with English summary]
  • 88. Kwapisz, B. 1983. Geological Map of Poland, Przedbórz sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 89. Labaume, P., Carrio-Schaffhauser, E., Gamond, J.F. and Renard, F. 2004. Deformation mechanism and fluid-driven mass transfers in the recent fault zones of the Corinth Rift (Greece). Comptes Rendus Geoscience, 336, 375-383.
  • 90. Lamarche, J., Bergerat, F., Lewandowski, M., Mansy, J.L., Świdrowska, J. and Wieczorek, J. 2002. Variscan to Alpine heterogeneous paleo-stress field above a major Palaeozoic suture in the Carpathian for eland (siuth-eastern Poland). Tectonophysics, 357, 55-80.
  • 91. Leszczyński, K. 1998. Lower Cretaceous (excluding Lower Berriasian and Upper Albian) - thickness. In: Dadlez, R., Marek, S. and Pokorski, J. (Eds), Palaeographical Atlas of the Epicontinental Permian and Mesozoic in Poland (1:2 500 000), plate 64. Polish Geological Institute; Warszawa. [in Polish with English summary]
  • 92. Łyczewska, J. 1971. Geological map of Poland, Busko Zdrój sheet (917), scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 93. Marcinowski, R. and Radwański, A. 1983. The Mid-Cretaceous transgression onto the Central Polish Uplands (marginal part of the Central European Basin). Zitteliana, 10, 65-95.
  • 94. Marek, S. 1988. Palaeothickness, lithofacies and palaeotectonics of the epicontinental Lower Cretaceous in Poland. Geological Quarterly, 32, 157-176.
  • 95. Marshak, S., Geise, P.A., Alvarez, W. and Engelder, T. 1982. Mesoscopic fault array of the northern Umbrian Apennine fold belt, Italy: Geometry of conjugate shear by pressure-solution slip. Geological Society of America Bulletin, 93, 1013-1022.
  • 96. Masse, J.-P., Philip, J. and Camoin, G. 1995. The Cretaceous Tethys. In: Nairn, A.E.M., Ricou, L.C., Vrielynck, B. and Dercourt, J. (Eds), The Tethys Ocean, pp. 215-236. Springer; New York.
  • 97. Mastella, L. and Rybak-Ostrowska, B. 2012. Tectonic control of tufa occurrences in the Podhale Synclinorium (Central Western Carpathians, southern Poland). Geological Quarterly, 56, 733-744.
  • 98. Mastella, L. 1988. Budowa i ewolucja strukturalna okna tektonicznego Mszany Dolnej, polskie Karpaty Zewnętrzne. Annales Societatis Geologorum Poloniae, 58, 53-173.
  • 99. Mastella, L. and Konon, A. 2002. Non-planar strike-slip Gnieździska-Brzeziny fault (SW Mesozoic margin of the Holy Cross Mountains central Poland). Acta Geologica Polonica, 52, 471-480.
  • 100. Matyja, B.A. 1977. The Oxfordian in the south-western margin of the Holy Cross Mts. Acta Geologica Polonica, 27, 41-64.
  • 101. Matyja, B.A. 2009. Development of the Mid-Polish Trough versus Late Jurassic evolution in the Carpathian Foredeep area. Geological Quarterly, 53, 49-62.
  • 102. Matyja, B.A. 2012. Mezozoik. In: Skompski, S. (Ed.), Góry Świętokrzyskie. 25 najważniejszych odsłonięć geologicznych, pp. 17-23. Uniwersytet Warszawski, Wydział Geologii; Warszawa.
  • 103. Matyja, B.A., Wierzbowski, A. and Drewniak, A. 1996. Węglanowe osady basenu późnojurajskiego zachodniego obrzeżenia Gór Świętokrzyskich. In: Karnkowski, P.H. (Ed.), Analiza basenów sedymentacyjnych a nowoczesna sedymentologia. Materiały konferencyjne V Krajowego Spotkania Sedymentologicznego, A1-16. Warszawa.
  • 104. Mazur, S., Krzywiec, P. and Scheck-Wenderoth, M. 2005. Different modes of Late Cretaceous-Early Tertiary inversion in the North German and Polish Basin. International Journal of Earth Sciences, 94, 782-798.
  • 105. Micklethwaite, S. and Cox, S.F. 2004. Fault-segment rupture, aftershock-zone fluid flow, and mineralization. Geology, 32, 813-816.
  • 106. Nemčok, M., Krzywiec, P., Wojtaszek, M., Ludhová, L., Klecker, R.A., Sercombe, W.J. and Coward, M.P. 2006. Tertiary development of the Polish and eastern Slovak parts of the Carpathian accretionary wedge: insights from balanced cross-sections. Geologica Carpathica, 57, 355-370.
  • 107. Nuriel, P., Weinberger, R., Rosenbaum, G., Golding, S.D., Zhao, J., Uysal, I.T., Bar-Matthews, M. and Gross, M.R. 2012. Timing and mechanism of late-Pleistocene calcite vein formation across the Dead Sea Fault Zone, northern Israel. Journal of Structural Geology, 36, 43-54.
  • 108. Ohmoto, H. and Rye, R.O. 1979. Isotope of sulfur and carbon. In: Barnes, H.L. (Ed.), Geochemistry of Hydrothermal Deposits, pp. 509-567. John Wiley & Sons; New York.
  • 109. Oliver, N.H.S. 1996. Review and classification of structural controls on fluid flow during regional metamorphism. Journal of Metamorphic Geology, 14, 477-492.
  • 110. Oszczypko, N. 2006. Late Jurassic-Miocene evolution of the Outer Carpathian fold-and-thrust belt and its foredeep basin (Western Carpathians, Poland). Geological Quarterly, 50, 169-194.
  • 111. Passchier, C.W. and Trouw, R.A.J. 1996. Microtectonics, 289 p. Springer Verlag; Berlin.
  • 112. Petit, J.P. 1987. Criteria for the sense of movement on fault surfaces in brittle rocks. Journal of Structural Geology, 9, 597-608.
  • 113. Pieńkowski, G. 2004. The epicontinental Lower Jurassic of Poland. Polish Geological Institute Special Papers, 12, 1-154.
  • 114. Pieńkowski, G.1991. Eustatically-controlled sedimentation in the Hettangian-Sinemurian (Early Jurassic) of Pland and Sweden. Sedimentology, 38, 503-518.
  • 115. Pili, É., Poitrsson, F. and Gratier, J-P. 2002. Carbon-oxygen isotope and trace element constraints on how fluids percolate faulted limestones from the San Andreas Fault system: partitioning of fluid sources and pathways. Chemical Geology, 190, 231-250.
  • 116. Piller, W.E., Harzhauser, M. and Mandic, O. 2007. Miocene Central Paratethys stratigraphy-current status and future directions. Stratigraphy, 4, 151-168.
  • 117. Plašienka, D., Grecula, P., Putiš, M., Kováč, M. and Hovorka, D. 1997. Evolution and structure of the Western Carpathians: an overview. In: Grecula, P., Hovorka, D. and Kováč, M. (eds), Geological Evolution of the Western Carpathians, pp. 1-24. Geocomplex; Bratislava.
  • 118. Pollard, D.D. and Segall, P. 1987. Theoretical displacements stresses near fractures in rocks: with applications to faults, joints, veins, dikes, and solution surfaces. In: Atkinson, B.K. (Ed.), Fracture Mechanics of Rocks, pp. 277-349. Academic Press; London.
  • 119. Pożaryski, W. 1964. Outline of Palaeozoic and Mesozoic tectonics of the Polish Lowland. Kwartalnik Geologiczny, 8, 1-41. [In Polish with English summary]
  • 120. Radwański, A. 1969. Lower Tortonian transgression onto the southern slopes of the Holy Cross Mts. Acta Geologica Polonica, 19, 1-164. [In Polish with English summary]
  • 121. Radwański, A. 1973. Lower Tortonian transgression onto the south-eastern and eastern slopes of the Holy Cross Mts. Acta Geologica Polonica, 23, 375-434. [In Polish with English summary]
  • 122. Radwański, A. and Górka, M. 2012. Wybrzeże morza mioceńskiego - Korytnica, Lubania i głazowisko klifowe w Skotnikach. In: Skompski, S. (Ed.), Góry Świętokrzyskie. 25 naj ważniejszych odsłonięć geologicznych, pp. 131-137. Uniwersytet Warszawski, Wydział Geologii; Warszawa.
  • 123. Ramsay, J.G. 1980. The crack-seal mechanism of rock deformation. Nature, 284, 135-139.
  • 124. Ramsay, J.M. and Chester, F.M. 2004. Hybrid fracture and the transition from extension fracture to shear fracture. Nature, 428, 63-66.
  • 125. Reading, H.G. 1980. Characteristics and recognition of strikeslip fault systems. In: Balance, P.F. (Ed.), Sedimentation in Oblique-slip Mobile Zones. Special Publications, International Association of Sedimentologists, 4, 7-26.
  • 126. Resak, M., Narkiewicz, M. and Littke, R. 2008. New basin modelling results from the Polish part of the Central European Basin system: implications for the Late Cretaceous- Early Paleogene structural inversion. International Journal of Earth Sciences, 97, 955-972.
  • 127. Riedel, W. 1929. Zur Mechanik Geologischer Brucherscheinungen. Zentral-blatt fur Mineralogie, Geologie und Paleontologie B, 354-368.
  • 128. Romanek, A. 1982. Geological Map of Poland, Chmielnik sheet (885), scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 129. Rosenbaum, J. and Sheppard, S.M. 1986. An isotopic study of siderites, dolomites and ankerites at high temperatures. Geochimica Cosmochimica Acta, 50, 1147-1150.
  • 130. Różycki, S.Z. 1961. Materiały do przeglądowej mapy geologicznej Polski. Region Świętokrzyski, arkusz Włoszczowa. Wydanie B zaktualizowane, skala 1:100 000. Wydawnictwa Geologiczne; Warszawa.
  • 131. Rybak-Ostrowska, B., Konon, A., Domonik, A., Uroda, J. and Poszytek, A. 2017. Shallow generated damage within non-planar strike-slip fault zones - role of the sedimentary rocks in the slip accommodation, SW Holy Cross Mountains, Poland. International Journal of Earth Sciences (Geologische Rundschau), 106, 1863-1888.
  • 132. Scholz, Ch.H. 2002. The Mechanics of Erthquakes and Faulting, 467 p. Cambridge University Press; Cambridge.
  • 133. Schreurs, G. 1994. Experiments on strike-slip faulting and block rotation. Geology, 22, 567-570.
  • 134. Schreurs, G. 2003. Fault development and interaction in distributed strike-slip shear zones: an experimental approach. In: Storti, F., Holdswoth, R.E. and Salvini, F. (Eds), Intraplate Strike-slip Deformation Belts. Geological Society, London, Special Publications, 210, 35-52.
  • 135. Segall, P. and Pollard, D.D. 1980. Mechanics of Discontinuous Faults. Journal of Geophysical Research, 85, 4337-4350.
  • 136. Senkowicz, E. 1955. Geological map of Poland, Pińczów sheet (884), scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 137. Senkowiczowa, H. 1961. The Röth and Muschelkalk on the southern slope of the Święty Krzyż Mts. between Czarna Nida and Chmielnik. Biuletyn Instytutu Geologicznego, 167, 41-89. [In Polish with English summary]
  • 138. Sibson, R.H. 1996. Structural permeability of fluid-driven fault-fracture meshes. Journal of Structural Geology, 18, 1031-1042.
  • 139. Sibson, R.H. 2000. Fluid involvement in normal faulting. Journal of Geodynamics, 29, 469-499.
  • 140. Slobodník, M., Melichar and R., Hurai, V., Bakker, R.J. 2012. Litho-stratigraphic effect on Variscan fluid flow within the Prague synform, Barrandain: Evidence based on C, O, Sr isotopes and fluid inclusions. Marine and Petroleum Geology, 35, 128-138.
  • 141. Stworzewicz, E., Prisyazhnyuk, V.A. and Górka, M. 2013. Systematic and palaeoecological study of Miocene terrestrial gastropods from Zwierzyniec (southern Poland). Annales Societatis Geologorum Poloniae, 83, 179-200.
  • 142. Suchy, V., Dobes, P., Filip, J., Stejskal, M. and Zeman, A. 2002. Conditions for veining in the Barrandian Basin (Lower Palaeozoic), Czech Republic: evidence from fluid inclusions and apatite fission track analysis. Tectonophysics, 348, 25- 50.
  • 143. Świdrowska, J. 2007. Kreda w regionie lubelskim-sedymentacja i jej tektoniczne uwarunkowania. Biuletyn Państwowego Instytutu Geologicznego, 422, 63-77.
  • 144. Świdrowska, J. and Hakenberg, M. 1999. Subsydencja i początki inwersji bruzdy śródpolskiej na podstawie analizy map miąższości i litofacji osadów górnokredowych. Przegląd Geologiczny, 47, 61-68.
  • 145. Świdrowska, J., Hakenberg, M., Poluhtovič, B., Seghedi, A. and Višnâkov, I. 2008. Evolution of the Mosozoic Bains on the southwestern edge of the East European Craton (Poland, Ukraine, Moldova, Romania). Studia Geologica Polonica, 130, 3-130.
  • 146. Sylvester, A.G. 1988. Strike slip faults. Geological Society of America Bulletin, 100, 1666-1703.
  • 147. Szajn, J. 1977. Geological Map of Poland, Nagłowice sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 148. Szajn, J. 1980. Geological Map of Poland, Włoszczowa sheet, scale 1:50,000. Wydawnictwa Geologiczne; Warszawa.
  • 149. Szajn, J. 1983. Geological Map of Poland, Oleszno sheet, scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 150. Uysal, I.T., Fenga, Y., Zhao, J., Altunel, E., Weatherley, D., Karabacak, V., Cengizd, O., Golding, S.D., Lawrence, M.G. and Collerson, K.D. 2007. U-series dating and geochemical tracing of late Quaternary travertine in co-seismic fissures. Earth and Planetary Science, 257, 450-462.
  • 151. Wakabayashi, J. 2007. Stepovers that migrate with respect to affected deposits: field characteristics and speculation on some details of their evolution. In: Cunningham, W.D. and Mann, P. (Eds), Tectonics of Strike-Slip Restraining and Releasing Bends. Geological Society, London, Special Publications, 290, 169-188.
  • 152. Wakabayashi, J., Hengesh, J.V. and Sawyer, T.L. 2004. Four- dimensional transform fault processes: progressive evolution of step-overs and bends. Tectonophysics, 392, 279- 301.
  • 153. Walczowski, A. 1973. Geological map of Poland, Stopnica sheet (918), scale 1:50 000. Wydawnictwa Geologiczne; Warszawa.
  • 154. Wibberley, C.J.A. and Shimamoto, T. 2003. Internal structure and permeability of major strike-slip fault zones: the Median Tectonic Line in Mie Prefecture, Southwest Japan. Journal of Structural Geology, 25, 59-78.
  • 155. Wiberley, C.A.J., Yielding, G. and Di Toro, G. 2008. Recent advances in the understanding of fault zone internal structure: a review. Geological Society, London, Special Publications, 299, 5-33.
  • 156. Woodcock, N.H. and Schubert, C. 1994. Continental strike-slip tectonics. In: Hancock, P.L. (Ed.), Continental Deformation, 251-263. Pergamon Press; New York.
  • 157. Zhang, Y., Schaubs, P.M., Zhao, C., Ord, A., Hobbs, B. and Barnicoat, A.C. 2008. Fault-related dilation, permeability enhancement, fluid flow and mineral precipitation patterns: numerical models. In: Wibberley, C.A.J., Kurz, W., Imber, J., Holdsworth, R.E. and Collettini, C. (Eds), The internal Structure of Fault Zones. Geological Society, London, Special Publications, 299, 239-255.
  • 158. Zheng, Y.F. 1999. Oxygen isotope fractionation in carbonate and sulfate minerals. Geochemical Journal, 33, 109-126.
  • 159. Zheng, Y.F. and Hoefs, J. 1993. Carbon and oxygen isotopic covariations in hydrothermal calcites. Theoretical modeling on mixing processes and application to Pb-Zn deposits in the Harz Mountains, Germany. Mineralium Deposita, 28, 79-89.
  • 160. Ziegler, P.A. 1982. Geological Atlas of Western and Central Europe. 130 p. Elsevier; Amsterdam.
  • 161. Ziegler, P.A. 1987. Late Cretaceous and Cenozoic intra-plate compressional deformations in the Alpine foreland - a geodynamic model. Tectonophysics, 137, 389-420.
  • 162. Ziegler, P.A. 1990a. Collision related intra-plate compression deformations in Western and Central Europe. Journal of Geodynamics, 11, 357-388.
  • 163. Ziegler, P.A. 1990b. Geological Atlas of Western and Central Europe (2nd edition). 239 p. Shell Internationale Petroleum Mij. BV and Geological Society; London.
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