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Alluvial karstification and paleodoline development in Eocene limestones, a case study from west Sohag City, Egypt: implications for causes and impacts

  • Tawfiq Mohamed Mahran
  • Abdallah Mohamed HassanEmail author
Original Paper
  • 84 Downloads

Abstract

The Late Oligocene pre-Eonile paleoriver flows northwesterly over the Eocene Limestone Plateau in the east central Western Desert, west of the Nile Valley (Sohag), building an alluvial plain and leading to the karstification of the limestone bedrock, as paleoerosional surfaces and paleodolines. Knowledge of this alluvial karstification is completed with the detailed studies of the sedimentary evolution of the fluvial system and its contemporary deposition. Analysis of the sedimentological and geomorphological features allows discussing the natural environmental conditions that favored karst in the past and its main genetic mechanisms. The architectural elements of the fluvial deposits indicate that they were deposited in a gravel-dominated braided fluvial system, characterized by high availability of water and sediment supplies. The current study proves that genesis of paleodolines was mainly related to this high water supply. Some of them were progressively filled by syn-sedimentary deformed unconsolidated deposits. Such deformation is due to dissolution of the underlying sagging synclinal limestone, conditioning the location of sinking waters where preferential dissolution and later suffosion took place. A model for the evolution of the paleodoline fills is proposed and interpreted in three different stages: (1) gravitational processes developed and disorganized gravels were remobilized and dragged toward the created paleodolines; (2) flooding of the paleodolines acted as lakes where Gilbert-type deltas and gravel slope deposits accumulated, exhibiting several unconformities interpreted as a result of continued subsidence of the paleodoline related to dissolution; and (3) nondeformed fluvial facies sealed the whole deposits, marking the end of the karstification process. Combinations of different types of factors that could cause karstic subsidence and associated hazards include soluble rock lithology, paleoclimate, and deformational structure.

Keywords

Karstification Nile Valley Paleodolines Geomorphology Geohazards Pre-Eonile 

Notes

Acknowledgments

The authors are deeply grateful to Prof. Dr. A.M. Al-Amri (the editor-in-chief) and the anonymous associate editor and reviewers for insightful comments and criticism that improved the original manuscript.

References

  1. Abdelkareem M, Ghoneim E, El-Baz F, Askalany M (2012) New insight on paleoriver development in the Nile basin of the Eastern Sahara. J Afr Earth Sci 62(1):35–40Google Scholar
  2. Abdeltawab S (2013) Karst liemstones geohazards in Egypt and Saudi Arabia. Inter J Geoengineer Case Histories 2(4):258–269Google Scholar
  3. Abu Seif ES (2015) Geological evolution of Nile Valley, west Sohag, upper Egypt: a geotechnical perception. Arab J Geosci 8:11049–11072Google Scholar
  4. Ahmed SM (1980) Geology of the area east and southeast of Sohag. M Sc thesis, Sohag Faculty of Sci, Assiut University, EgyptGoogle Scholar
  5. Basso A, Bruno E, Parise M, Pepe M (2013) Morphometric analysis of sinkholes in a karst coastal area of southern Apulia (Italy). Environ Earth Sci 70(6):2545–2559Google Scholar
  6. Beck BA (1986) Generalized genetic framework for the development of sinkholes and karst in Florida. USA Envir Geol and Water Sci 8(1–2):5–18Google Scholar
  7. Beggs TF, Ruth BE (1984) Factors controlling the collapse cavities. Proceedings 1st multidisciplinary conference on sinkholes, Orlado, Florida, 15–17 Oct, pp 183–188Google Scholar
  8. Benito G, Perez-Gonzalez F, Gutiérrez A, Machado MJ (1998) River response to Quaternary subsidence due to evaporite solution (Gállego River, Ebro Basin, Spain). Geomorphol 22(3–4):243–263Google Scholar
  9. Benito G, Perez-Gonzalez F, Gutiérrez A, Machado MJ (2000) Geomorphological and sedimentological features in Quaternary fluvial systems affected by solution-induced subsidence (Ebro Basin, NE Spain). Geomorphol 33(3–4):209–224Google Scholar
  10. Benito G, Sancho C, Pena JL, Machado M, Rhodes E (2010) Large-scale karst subsidence and accelerated fluvial aggradation during MIS6 in NE Spain: climatic and paleohydrological implications. Quat Sci Rev 29(19–20):694–2704Google Scholar
  11. Blair TC, McPherson JG (1994) Alluvial fan processes and forms. In: Abrahams AD, Parsons A (eds) Geomorphology of desert environments. Chapman Hall, London, pp 354–402Google Scholar
  12. Brinkmann R, Parise M, Dye D (2008) Sinkhole distribution in a rapidly developing urban environment: Hillsborough County, Tampa Bay area, Florida. Eng Geol 99(3–4):169–184Google Scholar
  13. Brook GA, Embabi NS, Ashour MM, Edwards RL, Cheng H, Cowart JB, Dabous AA (2002) Djara cave in the Western Desert of Egypt: morphology and evidence of Quaternary climatic change. Cave and Karst Sci 29(2):57–65Google Scholar
  14. Brookes IA (2001) Possible Miocene catastrophic flooding in Egypt’s Western Desert. J Afr Earth Sci 32(2):325–333Google Scholar
  15. Chen J (1988) Karst collapses in cities and mining areas China. Environ Geol Water Sci 12:29–35Google Scholar
  16. Coe JA, Godt JW, Parise M, Moscariello A (2003) Estimating debris-flow probability using fan stratigraphy, historic records, and drainage-basin morphology, Interstate 70 highway corridor, central Colorado, U.S.A. In: Rickenmann D, Chen C (Eds.), “Debris-flow hazards mitigation: mechanics, prediction, and assessment”, Proceedings 3rd international conference, Davos (Switzerland), 10–12 September 2003, 2:1085–1096Google Scholar
  17. Cooper AH, Gutiérrez F (2013) Dealing with gypsum karst problems: hazards, environmental issues and planning. Treatise on geomorphology. Karst Geomorphol 6:451–462Google Scholar
  18. Currin JL, Barfus BL (1989) Sinkhole distribution and characteristics in Pasco County, Florida. In: Beck B (ed) 3rd multidisciplinary conferences on sinkholes. AA Balkema, Rotterdam, pp 97–106Google Scholar
  19. De Waele J, Lauritzen SE, Parise M (2011a) On the formation of dissolution pipes in Quaternary coastal calcareous arenites in Mediterranean settings. Earth Surf Process Landf 36:143–157Google Scholar
  20. De Waele J, Gutierrez F, Parise M, Plan L (2011b) Geomorphology and natural hazards in karst areas: a review. Geomorphol 134(1–2):1–8Google Scholar
  21. Del Prete S, Iovine G, Parise M, Santo A (2010) Origin and distribution of different types of sinkholes in the plain areas of southern Italy. Geodin Acta 23(1/3):113–127Google Scholar
  22. Delaney C (2009) Seasonal controls on deposition of late Devensian glaciolacustrine sediments, central Ireland. In: Glacial sedimentary processes and products, Ch 10, pp 149–163Google Scholar
  23. Delle Rose M, Parise M (2002) Karst subsidence in south-central Apulia, southern Italy. Int J Speleol 31(1/4):181–199Google Scholar
  24. Delle Rose M, Federico A, Parise M (2004) Sinkhole genesis and evolution in Apulia, and their interrelations with the anthropogenic environment. Nat Hazards Earth Syst Sci 4:1–9Google Scholar
  25. Doğan U (2002) Subsidence dolines formed by gypsum karstification at the east of Çankiri. Gazi Eğitim Fakültesi Dergisi 22(1):67–82Google Scholar
  26. Dorn RI (1994) The role of climatic change in alluvial fan developmemt. In: Parsoms AJ, Abrahams AD (eds) Geomorphology of desert environments, 2nd edn. Chapman and Hall, London, pp 723–742Google Scholar
  27. El Aref M, Awadalah F, Ahmed S (1986) Karst landform development and related sediments in the Miocene rocks of the Red Sea coastal zone, Egypt. Geol Rund Sonderdruck Geologische Vereinigung Mending 75(3):781–790Google Scholar
  28. El Aref M, Abou Khadrah A, Lotfi Z (1987) Karst topography and karstification processes in the Eocene limestone plateau of El Bahariya oasis, Western Desert, Egypt. Z Geomorph NF 31(1):45–64Google Scholar
  29. El Deftar T, Issawi B, Abdallah A (1978) Contributions to the geology of Abu Tartur and adjacent areas, Western Desert, Egypt. Ann Geol Surv Egypt 8:51–90Google Scholar
  30. El Haddad BA (2014) Evolution of the geological history of the Egyptian Nile at Sohag area using sedimentlogical studies and remote sensing techniques. M Sc thesis, Sohag Faculty of Sci, Sohag University, Egypt. 216pGoogle Scholar
  31. El Hinnawi M, Abdallah A, Issawi B (1978) Geology of Abu Bayan, Bolaq Stretch, Western Desert, Egypt. Ann Geol Surv Egypt 8:19–50Google Scholar
  32. El-Baz F, Maingue M, Robinson CA (2000) Fluvio-aeolian dynamics in the north-eastern Sahara: the relationship between fluvial/aeolian systems and ground-water concentration. J Arid Environ 44(2):173–183Google Scholar
  33. El-Haddad BA, Youssef AM, El-Shater A, El-Khashab MH (2017) Slope stability hazard assessment using 3D remote sensing and field sketching techniques along Sohag- Red Sea- Cairo Highway, Egypt. 4 th world landslide forum, Ljubljana Slovenia Eu “landslide research and risk reduction for advancing culture of living with natural hazards” 2:407–418Google Scholar
  34. El-Naggar ZR (1970) On a proposed lithostratigraphic subdivision for the Late Cretaceous-Early Palaeocene succession in the Nile Valley, Egypt. UAR Seventh Arab Petroleum Congress, Kuwait, No 64, pp 3–49Google Scholar
  35. Eren M, Hatipoglu-Bagci Z (2010) Karst surface features of the hard laminated crust (caliche hardpan) in the Mersin area, southern Turkey. Acta Carsologica 39(1):93–102Google Scholar
  36. Fernald EA, Purdum E, Anderson JR, Krafft PA (1998) Water resources atlas of Florida. Institute of Sci and Public Affairs, Florida State University, Tallahassee FLGoogle Scholar
  37. Ford DC, Williams PW (2007) Karst geomorphology and hydrology, 2nd edn. Wiley, West Sussex, p 576Google Scholar
  38. Fryberger SG (1993) A review of aeolian bounding surfaces, with examples from the Permian Minnelusa Formation, USA. Geol Soc Lond, Spec Publ 73:167–197Google Scholar
  39. Galan C, Lagarde J (1988) Morphologie et evolution des caverns et formes superficielles dans les quartzites du Roraima (Venezuela). Karstologia 11–12:49–60Google Scholar
  40. Garfi G, Bruno D, Calcaterra D, Parise M (2007) Fan morphodynamics and slope instability in the Mucone River basin (Sila Massif, southern Italy): significance of weathering and role of land use changes. Catena 69(2):181–196Google Scholar
  41. Ghoneim E, Robinson C, El Baz F (2007) Radar topography data reveal drainage relics in the eastern. Sahara Inter J Remote Sens 28(8):1759–1772Google Scholar
  42. Grimes KG (2012) Surface karst features of the Judbarra, Gregory National Park, Northern Territory, Australia. Helictite 41:15–36Google Scholar
  43. Gueguen E, Formicola W, Martimucci M, Parise M, Ragone G (2012) Geological controls in the development of palaeo-karst systems of High Murge (Apulia). Rend Online Soc Geol Ital 21(1):617–619Google Scholar
  44. Guerrero J, Gutiérrez F, Lucha P (2004) Paleosubsidence and active subsidence due to evaporite dissolution in the Zaragoza area (Hueva River Valley, NE Spain): processes, spatial distribution and protection measures for transport roots. Eng Geol 72:309–329Google Scholar
  45. Gutiérrez F, Gutiérrez M, Marín C, Maldonado CY, Younger PL (2005) Subsidence hazard avoidance based on geomorphological mapping in the Ebro River Valley mantled evaporite karst terrain. Environ Geol 48:370–383Google Scholar
  46. Gutiérrez F, Cooper AH, Johnson KS (2008) Identification, prediction and mitigation of sinkhole hazards in evaporite karst areas. Environ Geol 53:1007–1022Google Scholar
  47. Gutiérrez F, Galve JP, Lucha P, Bonachea J, Jordá L, Jordá R (2009) Investigation of a large collapse sinkhole affecting a multi-storey building by means of geophysics and the trenching technique, Zaragoza City, NE Spain. Environ Geol 58:1107–1122Google Scholar
  48. Gutiérrez F, Soldati M, Audemars FA, Bălteanu D (2010) Recent advances in landslide investigation: issues and perspectives. Geomorphol 124(3-4):95–102Google Scholar
  49. Gutiérrez F, Parise M, De Waele J, Jourde H (2014) A review on natural and human-induced geohazards and impacts in karst. Earth-Sci Rev 138:61–88Google Scholar
  50. Gutiérrez-Elorza M, Gutiérrez-Santolalla F (1998) Geomorphology of the Tertiary gypsum formations in the Ebro depression (Spain). Geoderma 87:1–29Google Scholar
  51. Halliday W (2000) St Anthony’s Cave, Eastern Desert of Egypt. Speleodigest, Natl Spel Soc, Huntsville, AL, USA, (reprinted from Speleograph) 302:320pGoogle Scholar
  52. Halliday W (2003) The world’s largest gour: Wadi Sannur cavern, Egypt. NSS News 61(1):4–6Google Scholar
  53. Harvey A, Silva P, Mather A, Goy J, Stkes L, Zarza C (1999) The impact of Quaternary sea level and climatic change on coastal alluvial fans in Cabo de Geta ranges, southeast Spain. Geomorphol 28(1–2):1–22Google Scholar
  54. Horwitz H, Smith T (2003) Characteristics of stable and reactivated in-filled paleokarst features in west-central Florida. Amer Soci Civil Engin Geotech Speci Publ 122:50–60Google Scholar
  55. Hunt B, Smith B, Adams MT, Hiers S, Brown NI (2013) Cover-collapse sinkholes in the Cretaceous Edwards Limestone, central Texas (Poster). Proceedings 13th Multidisciplinary Conference on Sinkholes and the engineering and environmental impacts of karst, Carlsbad, New Mexico, 6–10 May, pp 89–102Google Scholar
  56. Iovine G, Parise M, Trocino A (2010) Breakdown mechanisms in gypsum caves of southern Italy, and the related effects at the surface. Z Geomorphol 54(2):153–178Google Scholar
  57. Iovine G, Vennari C, Gariano SL, Caloiero T, Lanza G, Nicolino N, Suriano S, Ferraro G, Parise M (2016) The “Piano dell’Acqua” sinkholes (San Basile, northern Calabria, Italy). Bull Eng Geol Environ 75(1):37–52Google Scholar
  58. Issawi B (2005) Archean-Phanerozoic birth and development of the Egyptian land. First Int Conf on the geology of the Tethys, Cairo University (II): 339–380Google Scholar
  59. Issawi B, McCauley JF (1992) The Cenozoic rivers of Egypt: the Nile problem. In: Freidman R, Adams B (eds) The followers of Horus, Egypt: studies Assoc Public 2, Oxbow Monograph 20. Park End Place, Oxford, pp 121–138Google Scholar
  60. Issawi B, Osman R (2008) Egypt during the Cenozoic: geological history of the Nile River. Bull Tethys Geol Soci Cairo 3:43–62Google Scholar
  61. Issawi B, El Hinnawi M, Francis M, Mazhar A (1999) The Phanerozoic geology of Egypt. Geol Surv, paper 76, 462pGoogle Scholar
  62. Issawi B, Francis M, Youssef EA, Osman, RA (2009) The Phanerozoic geology of Egypt: a geodynamic approach, 2 nd edn vol 81. Ministry of Petroleum and the Egyptian Mineral Resources Authority Special Publication Cairo, 571pGoogle Scholar
  63. Iwaniw E (1984) Lower Cambrian basin margin deposits in WE Leon, Spain—a model for valley-fill sedimentation in tectonically active, humid climatic setting. Sedimentol 31(1):91–110Google Scholar
  64. Kallmeier E, Breitkreuz C, Kiersnowski H, GeiBler M (2010) Issues associated with the distinction between climatic and tectonic controls on Permian alluvial fan deposits from the Kotzen and Barnim basins (north German Basin). Sediment Geol 223:15–34Google Scholar
  65. Kariem MS (2001) Geomorphology of the east side of the River Nile. Sohag Bull Geogr Soci Egypt 37:295–358Google Scholar
  66. Keheila EA, Soliman HA, El-Ayyat AM (1990) Litho-and biostratigraphy of the Lower Eocene carbonate sequence in Upper Egypt. Evidence for uplifting and resedimentation of the Paleocene section. J Afr Earth Sci 11(1/2):151–168Google Scholar
  67. Kindermann K, Bubenzer O, Nussbaum S, Riemer H, Darius F, Pollath N, Smettan U (2006) Palaeoenvironment and Holocene land use of Djara, Western Desert of Egypt. Quat Sci Rev 25:1619–1637Google Scholar
  68. Kjær KH, Sultan L, Krüger J, Schomacker A (2004) Architecture and sedimentation of outwash fans in front of the Myrdalsjökull ice cap, Iceland. Sediment Geol 172:139–163Google Scholar
  69. Klitszch E, List FK, Pohlmann G (1987) Geological map of Egypt. Conoco Coral and Egyptian General Petroleum Company, Cairo, Egypt, 24 sheets, scale 1:500,000Google Scholar
  70. Kochanov WE (1999) Sinkholes in Pennsylvania: Pennsylvania geological survey, 4th ser. Educational Series 11:33pGoogle Scholar
  71. Kovačič G, Ravbar N (2005) Mapping of hazards to karst groundwater on the Velika Planina Plateau (Slovenia). Actacarsologica 34(1):73–85Google Scholar
  72. Krüger J (1997) Development of minor outwash fans at Kötulujökull, Iceland. Quat Sci Rev 16:649–659Google Scholar
  73. Langer WH (2001) Potential environmental impacts of quarrying stone in karst: a literature review. US Geological Survey Open-File Report 0F-01-0484Google Scholar
  74. Lansbery L (2011) Geological and geomorphological evolution of the Egyptian Nile between Aswan and Kom Ombo: a remote sensing and field study approach. M Sc thesis. Missouri University of Science and Technology, Rolla, MO, 83pGoogle Scholar
  75. Lei M, Jian X, Yu L (2001) New advances of karst collapse research in China. In: Beck BF, Herring JG (eds) Geotechnical and environmental applications of karst geology and hydrology, pp 145–151Google Scholar
  76. Luzón A, Pérez A, Soriano MA, Pocoví A (2008) Sedimentary record of Pleistocene paleodoline evolution in the Ebro basin (NE Spain). Sediment Geol 205(1):1–13Google Scholar
  77. Luzón A, Rodríguez-lópez JP, Pérez AG, Soriano MA, Gil H, Pocoví A (2012) Karst subsidence as a control on the accumulation and preservation of aeolian deposits: a Pleistocene example from a proglacial outwash setting, Ebro Basin, Spain. Sedimentol 59:219–225Google Scholar
  78. Mahran TM, El Shater A, Youssef AM, El Haddad BA (2013) Facies analysis and tectonic-climatic controls on development of pre-Eonile sediments of the Egyptian Nile west Sohag. The 7th Inter Confer on the Geol of Africa, Assiut University, Egypt (abstract)Google Scholar
  79. Martini JEJ (1979) Karst in black reef quarzite near Kaapsehoop, eastern Transval. Ann South Afri Geol Surv 13:115–128Google Scholar
  80. McCauley JF, Breed CS, Schaber GG, McHugh WP, Issawi B, Haynes CV, Grolier MJ, El Kilani A (1986) Paleodrainages of the Eastern Sahara—the radar rivers revisited. SIR A/B implications for a mid-Tertiary trans-African drainage system. IEEE Transactions on Geosci and Remote Sens GE-24(4):624–648Google Scholar
  81. McConnico T, Bassett K (2007) Gravelly Gilbert-type fan delta on the Conway coast, New Zealand: foreset depositional processes and clast imbrications. Sediment Geol 198:147–166Google Scholar
  82. Miall AD (1996) The geology of fluvial deposits. Sedimentary facies, basin analysis, and petroleum geology. Springer, Berlin, p 582Google Scholar
  83. Mostafa A (2012) Caves of the Nile Valley (Governate of Assiut, Middle Egypt): a long-term interaction between human societies and their environment: Géomorphologie: relief, processes. Environment 18(1):37–44Google Scholar
  84. Mostafa A (2013) Paleokarst shafts in the Western Desert of Egypt: a unique landscape. Acta Carsologica 42(1):49–60Google Scholar
  85. Mulder T, Alexander J (2001) The physical character of subaqueous sedimentary density flow and their deposits. Sedimentol 48:269–299Google Scholar
  86. Nador A, Thamo-Boaso E, Magyari A, Babinszk E (2007) Fluvial response to tectonic and climatic change during Late Weichselian in the eastern part of the Pannonian Basin (Hungary). Sediment Geol 202:174–192Google Scholar
  87. Najib K, Jourde H, Séverin P (2008) A methodology for extreme groundwater surge predetermination in carbonate aquifers: groundwater flood frequency analysis. J Hydrol 352(1):1–15Google Scholar
  88. Nemec W, Postma G (1993) Quaternary alluvial fans in southwestern Crete: sedimentation processes and geomorphic evolution. In: Marzo M, Puigdefábregas C (eds) Alluvial sedimentation. Blackwell, Oxford Ch 18Google Scholar
  89. Omara S, El Tahlawi M, Hafez H (1970) The geology of the environs of Assuit. Bull Soc Geograph Egypt, Cairo, p 43Google Scholar
  90. Omara S, El Tahlawi MR, Abdel Kareem H (1973) Detailed geological mapping of the area between latitudes of Sohag and Gerga, east of the Nile Valley Egypt. Bull Fac Sci Assiut Univ 1:149–166Google Scholar
  91. Osleger DA, Heyvaert AC, Stoner JS, Verosub KL (2009) Lacustrine turbidites as indicators of Holocene storminess and climate: Lake Tahoe, California and Nevada. J Paleolimnol 42(1):103–122Google Scholar
  92. Parise M (2008) Rock failures in karst. In: Cheng Z, Zhang J, Li Z, Wu F, Ho K (Eds.), Landslides and engineered slopes. Proc 10th international symposium on landslides, Xi’an (China), June 30–July 4, 2008, 1:275–280Google Scholar
  93. Parise M (2010a) The impacts of quarrying in the Apulian karst. In: Carrasco F, La Moreaux JW, Duran Valsero JJ, Andreo B (eds) Advances in research in karst media. Springer, pp 441–447Google Scholar
  94. Parise M (2010b) Hazards in karst. In: Bonacci O (ed.), Proceedings international interdisciplinary scientific conference “Sustainability of the karst environment. Dinaric karst and other karst regions”, Plitvice Lakes (Croatia), 23–26 September 2009, IHP-UNESCO, series on groundwater no 2: pp 155–162Google Scholar
  95. Parise M (2015) A procedure for evaluating the susceptibility to natural and anthropogenic sinkholes. Georisk 9(4):272–285Google Scholar
  96. Parise M, Gunn J (2007) Natural and anthropogenic hazards in karst areas: recognition, analysis and mitigation. Geological Society, London, Special Publications, 279pGoogle Scholar
  97. Parise M, Lollino P (2011) A preliminary analysis of failure mechanisms in karst and man-made underground caves in southern Italy. Geomorphol 134(1–2):132–143Google Scholar
  98. Parise M, Ravbar N, Živanovic V, Mikszewski A, Kresic N, Mádl-Szönyi J, Kukuric N (2015a) Hazards in karst and managing water resources quality. Chapter 17. In: Stevanovic Z (ed) Karst aquifers—characterization and engineering. Professional Practice in Earth Sci,  https://doi.org/10.1007/978-3-319-12850-4-17, Springer, pp 601–687
  99. Parise M, Closson D, Gutierrez F, Stevanovic Z (2015b) Anticipating and managing engineering problems in the complex karst environment. Environ Earth Sci 74:7823–7835Google Scholar
  100. Parise M, Gabrovsek F, Kaufmann G, Ravbar N (2018) Recent advances in karst research: from theory to fieldwork and applications. In: Parise M, Gabrovsek F, Kaufmann G, Ravbar N (eds) Advances in karst research: theory, fieldwork and applications. Geological Society, London, Special Publications 466:1–24Google Scholar
  101. Pérez AG, Pueyo O, Gil H, Soriano MA, Luzón A, Pocoví A (2011) Gravel deltas associated with Pleistocene fluvial deposits affected by karstic collapses, and their study with GPR techniques (Ebro Basin, NE Spain). Geogaceta 50(2):117–120Google Scholar
  102. Perrin J, Noury G, Cartannaz C, Vanoudheusden E (2015) A multicriteria approach to karst subsidence hazard mapping supported by weight-of-evidence analysis. Eng Geol 197:296–305Google Scholar
  103. Philobbos ER, Abdel Rahman M (1990) Remarks on the Lithostratigraphy and sedimentological history of the Pliocene sediments of the Qena area. Bull Fac Sci Assiut Univ 19(2-F):15–33Google Scholar
  104. Piccini L, Mecchia M (2009) Solution weathering rate and origin of karst landforms and cave in the quartizite of Auyan-tepui (Gran Sabana, Venezuela). Geomorphol 106:15–25Google Scholar
  105. Picford M, Wanas H, Mein P, Soliman H (2008) Humid conditions in the Western Desert of Egypt during the Vahesian (Late Miocene). Bull Tethys Geol Soci, Cairo 3:63–79Google Scholar
  106. Pierson TC, Costa JE (1987) A rheologic classi-fication of subaerial sediment-water flows. In Costa JE, Wieczorek GF (eds.). Debris flows/avalanches: processes, recognition, and mitigation. Geol Soc Am Rev, Engineer Geol 7:1–12Google Scholar
  107. Ramos A, Sopeña A (1983) Gravel bars in low sinuosity streams (Permian and Triassic, central Spain): Spec Publs Inter Asso. Sedimentol 6:301–313Google Scholar
  108. Robinson C, El-Baz F, Ozdogan M, Ledwith M, Blanco D, Oakley S, lnzana J (2000) Use of radar data to delineate palaeodrainage flow directions in the Selima sand sheet, eastern Sahara. Photogramm Eng Remote Sens 66 (6):745–753Google Scholar
  109. Rust BR (1978) A classification of alluvial channel systems. In: Miall AD (ed) Fluvial sedimentology. Canadian Society of Petroleum Geologists Memoir 5, Calgary, Alberta, pp 187–198, 859pGoogle Scholar
  110. Said R (1960) Planktonic foraminifera from the Thebes formation, Luxor, Egypt. Micropaleont 6:277–286Google Scholar
  111. Said R (1962) The geology of Egypt. Elsevier, 377pGoogle Scholar
  112. Said R (1971) Explanatory notes to accompany the geological map of Egypt. Geol Surv Egypt. Paper no 55, 26pGoogle Scholar
  113. Said R (1990) The Cenozoic. In: Said R (ed) The geology of Egypt. Balkema AA, Rotterdam, pp 451–486Google Scholar
  114. Salim MG (2012) Selection of groundwater sites in Egypt, using geographic information systems, for desalination by solar energy in order to reduce greenhouse gases. J Adv Res 3(1):11–19Google Scholar
  115. Salvati R, Sasowsky ID (2002) Development of collapse sinkholes in areas of groundwater discharge. J Hydrol 264:1–11Google Scholar
  116. Selley RC (1982) An introduction into sedimentology. Academic, New York, 408pGoogle Scholar
  117. Sinclair WC, Stewart JW, Knutilla RL, Gilboy AE, Miller RL (1985) Types, features and occurrence of sinkholes in the karst of west-central Florida. US Geol Surv Water Resources Investig Rep:85–4126Google Scholar
  118. Smith ND (1974) Sedimentology and bar formation in the Upper Kicking Horse River, a braided outwash stream. J Geol 82(2):205–223Google Scholar
  119. Smith ND (1986) Proglacial fluvial environment. In: Ashley GM, Shaw J, Smith ND (eds) Glacial sedimentary environments. pp 85–134Google Scholar
  120. Soreghan GS, Soreghan MJ, Sweet DE, More KD (2009) Hot fan or cold outwash? Hypothesized proglacial deposition in the Upper Paleozoic Cutler Formation, western tropical Pangea. J Sediment Res 79:495–522Google Scholar
  121. Soriano MA, Luzón A, Pérez A, Pocovı A, Simón JL, Gil H (2010) Past and present doline development in the Central Ebro Basin (NE Spain) In Proceedings, 2° workshop Internazionale sinkholes, Roma, Istituto Superiore per la Protezione e la Ricerca Ambientale, pp 359–370Google Scholar
  122. Southard JB, Smith ND, Kuhnle RA (1984) Chutes and lobes: newly identified elements of braiding in shallow gravelly streams. In: Koster EH, Steel RJ (Eds.). Sedimentology of gravels and conglomerates. Canadian Soci of Petrol Geol Memo 10:51–59Google Scholar
  123. Taqieddin SA, Abderahman NS, Atallah M (2000) Sinkhole hazard along eastern Dead Sea shoreline area, Jordan: a geological and geotechnical consideration. Environ Geol 39:1237–1253Google Scholar
  124. Tarabees EA, Tewksbury BJ, Mehrtens CJ (2017) Audio-magnetotelluric surveys to constrain the origin of a network of narrow synclines in Eocene limestone, Western Desert, Egypt. J Afr Earth Sci 136:168–175Google Scholar
  125. Tewksbury BJ, Tarabees EA, Mehrtens CJ (2017) Origin of an extensive network of non-tectonic synclines in Eocene limestones of the Western Desert, Egypt. J Afr Earth Sci 136:148–167Google Scholar
  126. Trudgill ST (1985) Field observations of limestone weathering and erosion in the Malham District, North Yorkshire. Field Stud 6:201–236Google Scholar
  127. Waltham T (2001) Pinnacles and barchans in the Egyptian Desert. Geol Today 17(3):101–104Google Scholar
  128. Waltham T (2008) Sinkhole hazard case histories in karst terrains. Quarterly J of Engineer Geol and Hydrogeol 41(3):291–300Google Scholar
  129. Waltham AC, Fookes PG (2003) Engineering classification of karst ground conditions: speleogenesis and evolution of karst aquifers 3 (1). Quart J Engine Geol and Hydrogeol 36(2):101–118Google Scholar
  130. Waltham T, Bell FG, Culshaw MG (2005) Sinkholes and subsidence: karst and cavernous rocks in engineering and construction. Springer, Chichester, p 382Google Scholar
  131. Wanas HA, Pickford M, Mein P, Soliman H, Segalen I (2009) Late Miocene karst system at Sheikh Abdallah, between Bahariya and Farafra, Western Desert, Egypt: implications for palaeoclimate and geomorphology. Geol Acta 7(4):475–487Google Scholar
  132. White WB (1988) Geomorphology and hydrology of karst terrains. Oxford University Press, Oxford, p 464Google Scholar
  133. White WB (2002) Karst hydrology: recent developments and open questions. Eng Geol 65:85–105Google Scholar
  134. White WB (2007) Evolution and age relations of karst landscapes. Acta Carsologica 36:45–52Google Scholar
  135. Williams PW (2004) Dolines. In: Gunn J (ed) Encyclopedia of caves and karst sci. Fitzroy Dearborn, New York, pp 628–642Google Scholar
  136. Williams PW (2008) The role of the epikarst in karst and cave hydrogeology: a review. Int J Speleol 37(1):1–10Google Scholar
  137. Willis B (1993) Ancient river systems in the Himalayan foredeep, Chinji Village area, northern Pakistan. Sediment Geol 88:1–76Google Scholar
  138. Wilson WL (1995) Sinkhole and buried sinkhole densities and new sinkhole frequencies in karsts of northwest peninsular Florida. In: Beck BF (ed) Karst geohazards. Balkema, Rotterdam, pp 79–91Google Scholar
  139. Wright VP, Tucker ME (1991) Calcretes: an introduction. In: Wright VP, Tucker ME (eds.). Calcretes. IAS Reprint Series 2, Blackwell, Oxford, pp 1–22Google Scholar
  140. Yao BK, Yu JM, Guo Z (1987) Main geological problems in urban development in China: the role of geology in the urban development. Geol Soci Hong Kong Bull 3:257–265Google Scholar
  141. Youssef AM, Al-Harbi HM, Gutiérrez F, Zabramwi YA, Bulkhi AB, Zahrani SA, Bahamil AM, Zahrani AJ, Otaibi ZA, El-Haddad BA (2016) Natural and human-induced sinkhole hazards in Saudi Arabia: distribution, investigation, causes and impacts. Hydrogeol J 24(3):625–644Google Scholar
  142. Youssef AM, El-Shater A, El-Khashab MH, El-Haddad BA (2017) Coupling of field investigations and remote sensing data for karst hazards in Egypt: study around Sohag City. Arab J Geosci 10(11):235Google Scholar
  143. Youssef AM, El-Shater A, El-Khashab MH, El-Haddad BA (2018) Karst induced geo-hazards in Egypt: case study slope stability problems along some selected desert highways. In: Wasowski et al. (eds) Engineering geology and geological engineering for sustainable use of the Earth’s resources, urbanization, and infrastructure protection from geohazards: Sustainable Civil Infrastructures, Springer International Publishing, pp 149–164Google Scholar

Copyright information

© Saudi Society for Geosciences 2019

Authors and Affiliations

  • Tawfiq Mohamed Mahran
    • 1
  • Abdallah Mohamed Hassan
    • 1
    Email author
  1. 1.Geology Department, Faculty of ScienceSohag UniversitySohagEgypt

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