Top

Published in:

2019 | OriginalPaper | Chapter

Resistivity Characterization of Aquifer in Coastal Semiarid Areas: An Approach for Hydrogeological Evaluation

Authors : Mohamed Attwa, Halim Ali

Published in: Groundwater in the Nile Delta

Publisher: Springer International Publishing

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

In coastal and semiarid regions, the scientific interest lies in imaging the saltwater intrusion and delineating freshwater aquifer zones, respectively. Direct current resistivity (DCR) and induced polarization (IP) geophysical methods are commonly used to assess hydraulic characteristics of the aquifer. Particularly, the main reason for hydrogeophysical application of both DCR and IP is that the electrical characteristics of aquifers depend mainly on the geometry of the pore space and the porosity controlling the soil and rock effective transport properties. For preliminary hydrogeological investigations, these methods are applied at a wide range of field and laboratory scales. Accordingly, the vulnerable zone to the saltwater intrusion and/or contamination can be characterized by high accuracy. Furthermore, empirical and semiempirical relationships are widely used to predict the aquifer petrophysical characteristics, e.g., hydraulic conductivity, using the inversion results of such electrical methods. Equally, conventional and nonconventional DCR inversion algorithms are developed to reduce the nonuniqueness problem of actual resistivity interpretation and, consequently, to obtain more meaningful models than previously reported. As case histories, this chapter demonstrates the efficiency of DCR method for hydrogeological assessment in Nile Delta, Egypt, emphasizing on technical constraints to achieve sustainable development in coastal and semiarid areas.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Hydrogeophysical Characteristics of the Central Nile Delta Aquifer

next chapter Hydrogeophysical Investigations at El-Nubariya-Wadi El-Natrun Area, West Nile Delta, Egypt

Steuer A, Siemon B, Auken E (2009) A comparison of helicopter borne electromagnetics in frequency and time domain at the Cuxhaven valley in Northern Germany. Appl Geophys Sci 67:194–205CrossRef

Attwa M, Basokur A, Akca I (2014) Hydraulic conductivity estimation using direct current (DC) sounding data: a case study in East Nile Delta Egypt. Hydrgeol J 22:1163–1178. https://doi.org/10.1007/s10040–014–1107-3CrossRef

Ronczka M, Hellman K, Günther T, Wisén R, Dahlin T (2017) Electric resistivity and seismic refraction tomography: a challenging joint underwater survey at Äspö Hard Rock Laboratory. Solid Earth Sci 8:671–682CrossRef

Attwa M, Gemail KS, 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. Environ Earth Sci 75:784. https://doi.org/10.1007/s12665-016-5585-6 CrossRef

Goebela M, Adam P, Rosemary K (2017) Resistivity imaging reveals complex pattern of saltwater intrusion along Monterey coast. Hydrol Sci 551:746–755CrossRef

Farid A, Khalid P, Jadoon KZ, Jouini MS (2014) The depositional setting of the late quaternary sedimentary fill in southern Bannu basin northwest Himalayan fold and thrust belt Pakistan environ. Monit Assess Sci 8:6587–6604CrossRef

Muhammad M, Khalid P (2017) Hydrogeophysical investigations for assessing the groundwater potential in part of the Peshawar basin Pakistan. Arab J Sci Eng Sci 42:327–337CrossRef

Olatunji S, Musa A (2014) Estimation of aquifer hydraulic characteristics from surface geoelectrical methods: case study of the Rima basin North Western Nigeria. Arab Sci Eng 39:5475–5487CrossRef

Binley A, Hubbard S, Huisman J, Revil A, Robinson D, Singha K, Slater L (2015) The emergence of hydrogeophysics for improved understanding of subsurface processes over multiple scales. Water Resour Res Sci 51:3837–3866CrossRef

10.

Park S, Yi M-J, Kim J-H, Shin SW (2015) Electrical resistivity imaging (ERI) monitoring for groundwater contamination in an uncontrolled landfill South Korea. J Appl Geophys 135:1–7CrossRef

11.

Attwa M, Günther T (2013) Spectral induced polarization measurements for predicting the hydraulic conductivity in sandy aquifers. Hydrol Earth Syst Sci 17:4079–4094CrossRef

12.

Revil A, Binley A, Mejus L, Kessouri P (2015) Predicting permeability from the characteristic relaxation time and intrinsic formation factor of complex conductivity spectra. Water Resour Res 8:6672–6700CrossRef

13.

Ahmed AS, Jardani A, Revil A, Dupont JP (2016) Specific storage and hydraulic conductivity tomography through the joint inversion of hydraulic heads and self-potential data. Adv Water Resour 89:80–90CrossRef

14.

Maineult A, Jougnot D, Revil A (2017) Variations of petrophysical properties and spectral induced polarization in response to drainage and imbibition: a study on a correlated random tube network. Geophys J Int. https://doi.org/10.1093/gji/ggx474 CrossRef

15.

Shevnin V, Rodríguez OD, Mousatov A, Hernández DF, Martínez HZ, Ryjov A (2006) Estimation of soil petrophysical parameters from resistivity data: their application for oil contaminated sites characterization. Geophys J Int 45(3):179–193

16.

Aizebeokhai AP (2009) Geoelectrical resistivity imaging in environmental studies. In: Yanful EK (ed) Appropriate technologies for environmental protection in the developing world. Springer, Dordrecht, pp 297–305CrossRef

17.

Knoedel K, Lange G, Voigt H (2005) Direct resistivity methods. In: Environmental geology: handbook of field methods and case studies. Springer, New York, pp 205–237

18.

Weller A, Slater L, Nordsiek S, Ntarlagiannis D (2010) On the estimation of specific surface per unit pore volume from induced polarization: a robust empirical relation fits multiple datasets. Geophysics 4:105–112CrossRef

19.

Revil A, Kessouri P, Torres-Verdín C (2014) Electrical conductivity induced polarization and permeability of the Fontainebleau sandstone. Geophysics 5:301–318. https://doi.org/10.1190/geo2014-0036.1 CrossRef

20.

Revil A, Florsch N, Camerlynck C (2014) Spectral induced polarization porosimetry. Geophysics 198:1016–1033

21.

Wang M, Revil A (2010) Electrochemical charge of silica surface at high ionic strength in narrow channels. Journal of Coll Interface Sci 343:381–386CrossRef

22.

Falkenhagen H (1934) Electrolytes. Oxford University, Oxford

23.

Schwarz G (1962) A theory of the low-frequency dielectric dispersion of colloidal particles in electrolyte solution. J Phys Chem 66:2636–2642CrossRef

24.

Leroy P, Revil A, Kemna A, Cosenza P, Ghorbani A (2008) Spectralinduced polarization of water-saturated packs of glass beads. J Colloid Interface Sci 321:103–117CrossRef

25.

Marshall DJ, Madden TR (1959) Induced polarization a study of its causes. Geophysics 24:790–816CrossRef

26.

Bücker M, Hördt A (2013) Analytical modelling of membrane polarization with explicit parametrization of pore radii and the electrical double layer. Geophysics 194:804–813

27.

Attwa M (2012) Field application “Data acquisition processing and inversion”. In: Attwa M (ed) Electrical methods: practical guide for resistivity imaging and hydrogeophysics. LAP LAMBERT Academic Publishing GmbH and Co KG, Saarbrücken, Germany, pp 70–98

28.

Li Y, Oldenburg DW (1992) Approximate inverse mappings in DC resistivity problems. Geophys J Int 109:343–362CrossRef

29.

Martorana R, Lombardo L, Messina N, Luzio D (2013) Integrated geophysical survey for 3D modeling of a coastal aquifer polluted by seawater. Near Surf Geophys 11. https://doi.org/10.3997/1873–0604.2013006

30.

Vinegar HJ, Waxman MH (1984) Induced polarization of shaly sands. Geophysics 49:1267–1287CrossRef

31.

Vinegar HJ, Waxman MH (1987) In-situ method for determining pore size distribution capillary pressure and permeability. US Patent Sci 4:644–283

32.

Mazac O, Cislerova M, Kelly WE, Landa I, Venhodova D (1990) Determination of hydraulic conductivities by surface geoelectrical methods. In: Ward SH (ed) Geotechnical and environmental geophysics, vol 2. Society of Exploration Geophysicists, Tulsa, OK, pp 125–131

33.

Slater L (2007) Near surface electrical characterization of hydraulic conductivity: from petrophysical properties to aquifer geometries – a review. Surv Geophys 28:169–197CrossRef

34.

Börner FD, Schopper W, Weller A (1996) Evaluation of transport and storage properties in the soils and groundwater zone from induced polarization measurements. Geophysics 44:583–601

35.

Pape H, Riepe L, Schopper JR (1987) Theory of self-similar network structures in sedimentary and igneous rocks and their investigation with microscopical and physical methods. Microscopy 148:121–147CrossRef

36.

Hördt A, Druiventak A, Blaschek R, Binot F, Kemna A, Kreye P, Zisser N (2009) Case histories of hydraulic conductivity estimation with induced polarization at the field scale. Near Surf Geophys 7:529–545CrossRef

37.

Slater L, Lesmes D (2002) Electric-hydraulic relationships observed for unconsolidated sediments. Water Resour Res 10:1213. https://doi.org/10.1029/2001WR00107.2002 CrossRef

38.

Zisser N, Kemna A, Nover G (2010) Relationship between low-frequency electrical properties and hydraulic permeability of low-permeability sandstones. Geophysics 3:131–141CrossRef

39.

Silvester PP, Ferrari RL (1990) Finite elements for electrical engineers. 2nd edn. Cambridge University Press, Cambridge, UK. 516 p

40.

Sasaki Y (1994) 3-D resistivity inversion using the finite-element method. Geophysics 59(11):1839–1848. https://doi.org/10.1190/1.1443571 CrossRef

41.

Szalai S, Koppan A, Szokoli K, Szarka L (2013) Geoelectric imaging properties of traditional arrays and of the optimized Stummer configuration. Near Surf Geophys 11. https://doi.org/10.3997/1873-0604.2012058 CrossRef

42.

Blaschek R, Hördt A, Kemna A (2008) A new sensitivity-controlled focusing regularization scheme for the inversion of induced polarization data based on the minimum gradient support. Geophysics 73(2):F45–F54CrossRef

43.

Akca I, Basokur AT (2010) Extraction of structure-based geoelectric models by hybrid genetic algorithms. Geophysics 75(1):F15–F22CrossRef

Title: Resistivity Characterization of Aquifer in Coastal Semiarid Areas: An Approach for Hydrogeological Evaluation
Authors: Mohamed Attwa
Halim Ali
Publisher: Springer International Publishing
Book: Groundwater in the Nile Delta
Print ISBN: 978-3-319-94282-7

Electronic ISBN: 978-3-319-94283-4

Copyright Year: 2019
DOI: https://doi.org/10.1007/698_2017_210