Abstract
Geological structures introduce heterogeneity along deformed strata, which in turn exert a strong control on regional groundwater occurrences and water flow. We developed and applied procedures of structural, borehole and direct current resistivity (DCR) data to (1) figure out a reliable structural model of a fault-related dome, (2) visualize the relationship between structural complexity and aquifers geometry and (3) characterize the fault damage zones and its related sealing potentialities. The present approach was applied at the northern Eastern Desert, Egypt, considering its complex deformation history. To alleviate the uncertainties and artifacts in solving the DCR inverse problem, advanced and non-conventional inversion schemes were applied. Moreover, fault seal potentialities were assessed by applying the shale gouge ratio (SGR) estimation to predict the groundwater pathway flow. The main findings include: (a) The DCR measurements can be considered as a complementary tool to visualize the relationship between subsurface structures and aquifers geometry at highly deformed areas; (b) detailed surface structural data analysis combined with sophisticated inversion algorithms application can increase the reliability of the constructed geo-electrical cross sections for deep and large-scale geological surveys; and (c) the structural modeling of geological units and faults distribution contributes to clarify hydrogeological settings and aquifers connectivity. The approach can be readily applied elsewhere, as long as detailed structural analysis, geometric parameters and high-resolution DCR resistivity data are available.
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References
Abotalib, A. Z., Heggy, E., Scabbia, G., & Mazzoni, A. (2019). Groundwater dynamics in fossil fractured carbonate aquifers in Eastern Arabian Peninsula: A preliminary investigation. Journal of Hydrology,571, 460–470.
Abou Heleika, M. M., & Atwia, M. G. (2015). Integrated electrical resistivity and hydrogeological studies for delineating the Miocene aquifer at Eastern side of Nile Delta, Egypt. Arabian Journal of Geosciences,8, 4657. https://doi.org/10.1007/s12517-014-1575-8.
Akça, I., & Basokur, A. T. (2010). Extraction of structure-based geoelectric models by hybrid genetic algorithms. Geophysics,75, 15–22.
Allmendinger, R. W., Cardozo, N. C., & Fisher, D. (2012). Structural geology algorithms: Vectors & tensors. Cambridge: Cambridge University Press.
Attwa, M., Akça, I., Basokur, A., & Günther, T. (2014). Structure-based geoelectrical models derived from genetic algorithms: A case study for hydrogeological investigations along Elbe River coastal area, Germany. Journal of Applied Geophysics,103, 57–70.
Attwa, M., Gmeail, K. S., & Eleraki, M. (2016). Use of salinity and resistivity measurements to study the coastal aquifer salinization in a semi-arid region: A case study in northeast Nile Delta, Egypt. Environmental Earth Sciences,75, 784. https://doi.org/10.1007/s12665-016-5585-6.
Attwa, M., & Günther, T. (2012). Application of spectral induced polarization (SIP) imaging for characterizing the near surface geology: An environmental case study at Schillersalge, Germany. Australian Journal of Applied Sciences,6(9), 693–701.
Attwa, M., Günther, T., Grinat, M., & Binot, F. (2009). Transimissivity estimation from sounding data of Holocene tidal flat deposits in the North Eastern part of Cuxhaven, Germany. In Near surface 2009—15th European meeting of environmental and engineering geophysics, Dublin, Ireland.
Attwa, M., & Henaish, A. (2018). Regional structural mapping using a combined geological and geophysical approach—A preliminary study at Cairo-Suez district, Egypt. Journal of African Earth Sciences,144, 104–121.
Basokur, A. T., Akça, I., & Siyam, N. W. A. (2007). Hybrid genetic algorithms in view of the evolution theories with application for the electrical sounding method. Geophysical Prospecting,55, 393–406.
Benabdelouahab, S., Salhi, A., Himi, M., El Messari, J. E. S., & Ponsati, A. C. (2019). Geoelectrical investigations for aquifer characterization and geoenvironmental assessment in northern Morocco. Environmental Earth Sciences,78, 209. https://doi.org/10.1007/s12665-019-8221-4.
Benavente-Marín, M., & Jabaloy-Sánchez, A. (2017). 3D geometry of superposed folds in a large-scale refolded fault surface using geostatistical methods (internal zones of the Betic Cordillera, SE Spain). Journal of Iberian Geology. https://doi.org/10.1007/s41513-017-0033-3.
Bense, V. F., Gleeson, T., Loveless, S. E., Bour, O., & Scibek, J. (2013). Fault zone hydrogeology. Earth-Science Reviews,127, 171–192.
Bense, V. F., & Person, M. (2006). Faults as conduit–barrier systems to fluid flow in siliciclastic sedimentary aquifers. Water Resources Research. https://doi.org/10.1029/2005WR004480.
Dewing, K., Springer, A., Guest, B., & Hadlari, T. (2016). Geological evolution and hydrocarbon potential of the salt-cored Hoodoo Dome, Sverdrup Basin, Arctic Canada. Marine and Petroleum Geology,71, 134–148.
El Bastawesy, M., Attwa, M., Abdel Hafeez, T. H., & Gad, A. (2019). Flash floods and groundwater evaluation for the non-gauged dryland catchment using remote sensing, GIS and DC resistivity data: A case study from the Eastern Desert of Egypt. Journal of African Earth Sciences,152, 245–255.
El Haddad, I. M. (2002). Hydrogeological studies and their environmental impact on future management and sustainable development of the new communities and their surroundings, east of the Nile Delta, Egypt. Dissertation, University of Mansoura, Egypt.
Eleraki, M., Gadallah, M., Gemail, K., & Attwa, M. (2010). Application of resistivity method in environmental study of the appearance of soil water in the central part of Tenth of Ramadan City, Egypt. Quarterly Journal Engineering Geology and Hydrogeology,43, 171–184.
El-Fayoumy, I. F. (1968). Geology of ground water supplies in the region east of the Nile Delta and its extension in North Sinai. Ph.D. thesis, Cairo University, Cairo, Egypt.
El-Sawy, E. K., Eldougdoug, A., & Gobashy, M. (2018). Geological and geophysical investigations to delineate the subsurface extension and the geological setting of Al Ji’lani layered intrusion and its mineralization potentiality, Ad Dawadimi District, Kingdom of Saudi Arabia. Arabian Journal of Geosciences,11, 32. https://doi.org/10.1007/s12517-017-3368-3.
Erkül, F., Erkül, S. T., Manap, H. S., & Çolak, C. (2017). An extensional and transtensional origin of elongated magmatic domes and localised transfer faults in the northern Menderes metamorphic core complex, western Turkey. Geodinamica Acta,29, 139–159. https://doi.org/10.1080/09853111.2017.1343523.
Farag, I., & Ismail, M. M. (1959). A contribution to the structure of the area east of Helwan. Egyptian Journal of Geology,3, 71–86.
Fossen, H. (2010). Structural geology. Cambridge: Cambridge University Press.
Günther, T. (2004). Inversion methods and resolution analysis for the 2D/3D reconstruction of resistivity structures from DC-measurements. Dissertation for Doctoral Degree. University of mining and technology, Freiberg, Germany.
Gupta, R. K., Agrawal, M., Pal, S. K., Kumar, R., & Srivastava, S. (2019). Site characterization through combined analysis of seismic and electrical resistivity data at a site of Dhanbad, Jharkhand, India. Environmental Earth Sciences,78, 226. https://doi.org/10.1007/s12665-019-8231-2.
Hammam, A., Gaber, A., Abdelwahed, M., & Hammed, M. (2018). Geological mapping of the Central Cairo-Suez District of Egypt, using space-borne optical and radar dataset. The Egyptian Journal of Remote Sensing and Space Science. https://doi.org/10.1016/j.ejrs.2018.11.004.
Henaish, A. (2018a). Fault-related domes: Insights from sedimentary outcrops at the northern tip of the Gulf of Suez rift, Egypt. Marine and Petroleum Geology,91, 202–210. https://doi.org/10.1016/j.marpetgeo.2018.01.009.
Henaish, A. (2018b). Soft-linkage transfer zones: Insights from the Northern Eastern Desert, Egypt. Marine and Petroleum Geology,95, 265–275. https://doi.org/10.1016/j.marpetgeo.2018.05.005.
Henaish, A., & Attwa, M. (2018). Internal structural architecture of a soft-linkage transfer zone using outcrop and DC resistivity data: Implications for preliminary engineering assessment. Engineering Geology,244, 1–13.
Herrmann, B. (2017). Evidence for a subsurface Ordovician meteorite impact near Ingalls, Oklahoma. AAPG Bulletin,68, 20–31.
Hussein, A. (2001). Hydrogeological and geophysical studies for evaluation of groundwater potentialities at Cairo-Bilbeis district, Egypt. Dissertation, University of Suez Canal, Ismailia, Egypt.
Ismael, A. M. A. (2007). Application of remote sensing, GIS, and groundwater flow modeling in evaluating groundwater resources: Two case studies; East Nile Delta, Egypt and Gold Valley, California, USA. Dissertation, University of Texas, El Paso, USA.
Kim, J. H., Yi, M. J., Park, S. G., & Kim, J. G. (2009). 4-D inversion of DC resistivity monitoring data acquired over a dynamically changing earth model. Journal of Applied Geophysics,68, 522–532.
Ladevèze, P., Rivard, C., Lavoie, D., Séjourné, S., Lefebvre, R., & Bordeleau, G. (2019). Fault and natural fracture control on upward fluid migration: Insights from a shale gas play in the St. Lawrence Platform, Canada. Hydrogeology Journal,27, 121. https://doi.org/10.1007/s10040018-1856-5.
Larsen, L. G., Ma, J., & Kaplan, D. (2017). How important is connectivity for surface water fluxes? A generalized expression for flow through heterogeneous landscapes. Geophysical Research Letters,44, 10349–10358. https://doi.org/10.1002/2017GL075432.
Lehner, F. K., & Pilaar, W. F. (1997). The emplacement of clay smears in synsedimentary normal faults: Inference from field observations near Frechen, Germany. In P. Moeller-Pedersen & A. G. Koester (Eds.), Hydrocarbon seals. NPF special publication 7 (pp. 39–50). Amsterdam: Elsevier.
Magaia, L. A., Goto, T., Masoud, A., & Koike, K. (2018). Identifying groundwater potential in crystalline basement rocks using remote sensing and electromagnetic sounding techniques in Central Western Mozambique. Natural Resources Research,27, 275. https://doi.org/10.1007/s11053-017-9360-5.
Manuel, R., Brito, M., Chichorro, M., & Rosa, C. (2017). Remote sensing for mineral exploration in central Portugal. Minerals,7(10), 184. https://doi.org/10.3390/min7100184.
Misonou, T., Asaue, H., Yoshinaga, T., Matsukuma, Y., Koike, K., & Shimada, J. (2013). Hydrogeologic-structure and groundwater-movement imaging in tideland using electrical sounding resistivity: A case study on the Ariake Sea coast, southwest Japan. Hydrogeology Journal,21, 1593–1603. https://doi.org/10.1007/s10040-013-1022-z.
Moustafa, A. R., & Abd-Allah, M. A. (1991). Structural setting of the central part of the Cairo-Suez District. Middle East Research Center, Ain Shams University, Earth Science Series 5, (pp. 133–145).
Qin, Y., & Lu, J. (2019). Prediction of coal mine water hazards: A case study from the Huainan Coalfield. Arabian Journal of Geosciences,12, 83. https://doi.org/10.1007/s12517-019-4263-x.
Raji, W. O., & Adeoye, T. O. (2017). Geophysical mapping of contaminant leachate around a reclaimed open dumpsite. Journal of King Saud University - Science,29(3), 348–359. https://doi.org/10.1016/j.jksus.2016.09.005.
RIGW/IWACO. (1990). Vulnerability of groundwater pollution in the Nile Valley and Delta. TN, 70. 130-89-02, Cairo.
RIGW/IWACO. (1991). Groundwater potential in the Nile Valley and Delta. International report, Cairo, Egypt.
RIGW/IWACO. (1994). Environmental management of groundwater resources project. Inception Report.
Shukri, N. M. (1954). On cylindrical structures and coloration of Gebel Ahmar near Cairo, Egypt. Bulletin of Faculty of Science, Cairo University,32, 1–23.
Shukri, N. M., & Akmal, M. G. (1953). The geology of Gebel El Nasuri and Gebel El-Anqabiya district. Bulletin de la Société de géographied’Egypte,26, 243–276.
Telford, W. M., Geldart, L. P., & Sheriff, R. E. (1990). Applied geophysics (2nd ed.). Cambridge: Cambridge University Press.
Udphuay, S., Günther, T., Everett, M. E., Warden, R. R., & Briaud, J.-L. (2011). Three-dimensional resistivity tomography in extreme coastal terrain amidst dense cultural signals: Application to cliff stability assessment at the historic D-Day site. Geophysical Journal International,185, 201–220.
Usman, N., Abdullah, K., & Nawawi, M. (2019). Investigating the performance of combined resistivity model using different electrode arrays configuration. Arabian Journal of Geosciences,12, 125. https://doi.org/10.1007/s12517-018-4192-0.
Yi, M. J., Kim, J. H., & Chung, S. H. (2003). Enhancing the resolving power of least squares inversion with active constraint balancing. Geophysics,68, 931–941.
Yielding, G., Freeman, B., & Needham, D. T. (1997). Quantitative fault seal prediction. AAPG Bulletin,81(6), 897–917.
Yilmaz, S., & Koksoy, M. (2017). Electrical resistivity imaging and dye tracer test for the estimation of water leakage paths from reservoir of Akdeğirmen Dam in Afyonkarahisar, Turkey. Environmental Earth Sciences,76, 829. https://doi.org/10.1007/s12665-017-7174-8.
Acknowledgments
The authors would like to express appreciation and thanks to Prof. A. Basokur (Ankara Uni. Turkey) and J. H. Kim (the geosciences and mineral resources Korean institute) for great assistance and support with DCR inversion software through preparing our paper. Special thanks are due to R.W. Allmendinger for the permission of using Stereonet v.9 for structural data analysis in the present work. Many thanks are to Structural Geophysics Group (SGG) members for valuable discussions. The authors would like to thank the anonymous reviewers for helpful comments. Special thanks are also due to the Editor Prof Dr. John Carranza, whose patience and insightful suggestions have led to a concise revised version.
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Attwa, M., Henaish, A. & Zamzam, S. Hydrogeologic Characterization of a Fault-Related Dome Using Outcrop, Borehole and Electrical Resistivity Data. Nat Resour Res 29, 1143–1161 (2020). https://doi.org/10.1007/s11053-019-09504-6
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DOI: https://doi.org/10.1007/s11053-019-09504-6