Register      Login
Exploration Geophysics Exploration Geophysics Society
Journal of the Australian Society of Exploration Geophysicists
RESEARCH ARTICLE

Structural interpretation of the Ifal Basin in north-western Saudi Arabia from aeromagnetic data: hydrogeological and environmental implications

Eslam Elawadi 1 2 4 Haider Zaman 3 Awni Batayneh 1 Saad Mogren 1 Abdalaziz Laboun 1 Habes Ghrefat 1 Taisser Zumlot 1
+ Author Affiliations
- Author Affiliations

1 Department of Geology and Geophysics, King Saud University, PO Box 2455, Riyadh 11451, Saudi Arabia.

2 Airborne Exploration Division, Nuclear Materials Authority, PO Box 530, Maadi, Cairo, Egypt.

3 Department of Geology, Faculty of Science, Taibah University, Madinah, Saudi Arabia.

4 Corresponding author. Email: eelawadi@ksu.edu.sa

Exploration Geophysics 44(4) 251-263 https://doi.org/10.1071/EG12069
Submitted: 2 November 2012  Accepted: 17 July 2013   Published: 2 September 2013

Abstract

The Ifal (Midyan) Basin is one of the well defined basins along the Red Sea coast, north-western Saudi Arabia. Location, geometry, thick sedimentary cover and structural framework qualify this basin for groundwater, oil and mineral occurrences. In spite of being studied by two airborne magnetic surveys during 1962 and 1983, structural interpretation of the area from a magnetic perspective, and its uses for hydrogeological and environmental investigations, has not been attempted. This work thus presents interpretation of the aeromagnetic data for basement depth estimation and tectonic framework delineation, which both have a role in controlling groundwater flow and accumulation in the Ifal Basin. A maximum depth of 3.5 km is estimated for the basement surface by this study. In addition, several faulted and tilted blocks, perpendicularly dissected by NE-trending faults, are delineated within the structural framework of the study area. It is also observed that the studied basin is bounded by NW- and NE-trending faults. All these multi-directional faults/fracture systems in the Ifal Basin could be considered as conduits for groundwater accumulation, but with a possibility of environmental contamination from the surrounding soils and rock bodies.

Key words: groundwater aquifers, Ifal Basin, magnetic interpretation, structural mapping.


References

Baranov, V., and Naudy, H., 1964, Numerical calculation of the formula of reduction to the magnetic pole: Geophysics, 29, 67–79
Numerical calculation of the formula of reduction to the magnetic pole:Crossref | GoogleScholarGoogle Scholar |

Batayneh, A., Ghrefat, H., and Diabat, A., 2012a, Lineament characterization and their tectonic significance using gravity data and field studies in the Al-Jufr area, southeastern Jordan Plateau: Journal of Earth Science, 23, 873–880
Lineament characterization and their tectonic significance using gravity data and field studies in the Al-Jufr area, southeastern Jordan Plateau:Crossref | GoogleScholarGoogle Scholar |

Batayneh, A., Laboun, A., Qaisy, S., Ghrefat, H., Zumlot, T., Zaman, H., Elawadi, E., Mogren, S., and Al-Qudah, K., 2012b, Assessing groundwater quality of the shallow alluvial aquifer system in the Midyan Basin, northwestern Saudi Arabia: Arab Gulf Journal of Scientific Research, 30, 7–13
| 1:CAS:528:DC%2BC38Xht1ynsrvK&md5=faeb47d9bc9a0b53ee6f243c31b3d746CAS |

Batayneh, A., Ghrefat, H., Zaman, H., Mogren, S., Zumlot, T., Elawadi, E., Laboun, A., and Qaisy, S., 2012c, Assessment of the physicochemical parameters and heavy metals toxicity: application to groundwater quality in unconsolidated shallow aquifer system: Research Journal of Environmental Toxicology, 6, 169–183
Assessment of the physicochemical parameters and heavy metals toxicity: application to groundwater quality in unconsolidated shallow aquifer system:Crossref | GoogleScholarGoogle Scholar |

Blakely, R. J., and Simpson, R. W., 1986, Approximating edges of source bodies from magnetic or gravity anomalies: Geophysics, 51, 1494–1498
Approximating edges of source bodies from magnetic or gravity anomalies:Crossref | GoogleScholarGoogle Scholar |

Clark, M., 1987, Explanatory notes to the geologic map of the Al Bad’ Quadrangle, sheet 28A, Kingdom of Saudi Arabia: Saudi Arabian Deputy Ministry for Mineral Resources, Geoscience Map Series GM-81A, C, scale 1 : 250,000 with text, 46 pp.

Cooper, G. R. J., and Cowan, D. R., 2006, Enhancing potential field data using filters based on the local phase: Computers & Geosciences, 32, 1585–1591
Enhancing potential field data using filters based on the local phase:Crossref | GoogleScholarGoogle Scholar |

Cordell, L. E., and Grauch, V. J. S., 1985, Mapping basement magnetization zones from aeromagnetic data in the San Juan Basin, New Mexico, in W. J. Hinze, ed., The utility of regional gravity and magnetic anomaly maps: Society of Exploration Geophysicists, Tulsa, 181–197.

Grauch, V. J. S., Hudson, M. N., and Minor, S. A., 2001, Aeromagnetic expression of faults that offset basin fill, Albuquerque basin, New Mexico: Geophysics, 66, 707–720
Aeromagnetic expression of faults that offset basin fill, Albuquerque basin, New Mexico:Crossref | GoogleScholarGoogle Scholar |

Hood, P. J., 1965, Gradient measurements in aeromagnetic surveying: Geophysics, 30, 891–902
Gradient measurements in aeromagnetic surveying:Crossref | GoogleScholarGoogle Scholar |

Hughes, G., and Johnson, R., 2005, Lithostratigraphy of the Red Sea region: GeoArabia, 10, 140–159

Hughes, G., Perincek, D., Abu-Bshait, A., and Jarad, A., 1999, Aspects of Ifal geology, Saudi Arabian Red Sea: Saudi Aramco Journal of Technology, Winter 1999/2000, 12–42

Jacobsen, B. H., 1987, A case for upward continuation as a standard separation filter for potential-field maps: Geophysics, 52, 1138–1148
A case for upward continuation as a standard separation filter for potential-field maps:Crossref | GoogleScholarGoogle Scholar |

Laboun, A., 2012, Did glaciers exist during Pleistocene in the Midyan region, northwest corner of the Arabian Peninsula?: Arabian Journal of Geosciences, 5, 1333–1339
Did glaciers exist during Pleistocene in the Midyan region, northwest corner of the Arabian Peninsula?:Crossref | GoogleScholarGoogle Scholar |

Miller, H. G., and Singh, V., 1994, Potential field tilt - a new concept for location of potential field sources: Journal of Applied Geophysics, 32, 213–217
Potential field tilt - a new concept for location of potential field sources:Crossref | GoogleScholarGoogle Scholar |

Moreau, F., Gibert, D., Holschneider, M., and Saracco, G., 1999, Identification of sources of potential fields with the continuous wavelet transform: basic theory: Journal of Geophysical Research, 104, 5003–5013
Identification of sources of potential fields with the continuous wavelet transform: basic theory:Crossref | GoogleScholarGoogle Scholar |

Naudy, H., 1971, Automatic determination of depth on aeromagnetic profiles: Geophysics, 36, 717–722
Automatic determination of depth on aeromagnetic profiles:Crossref | GoogleScholarGoogle Scholar |

Pilkington, M., and Keating, P., 2004, Contact mapping from gridded magnetic data - a comparison of techniques: Exploration Geophysics, 35, 306–311
Contact mapping from gridded magnetic data - a comparison of techniques:Crossref | GoogleScholarGoogle Scholar |

Rama Rao, Ch., Lakshmi, M. P., and Ram Babu, H. V., 2002, Delineation of new structural controls using aeromagnetic and their relation with the occurrence of ground water in an exposed basement complex in a part of South Indian shield: Proceedings of the International Groundwater Conference on Sustainable Development and Management of Groundwater Resources in Semi-Arid Region with Special Reference to Hard Rocks, 3–10.

Ravat, D., 1996, Analysis of the Euler method and its applicability in environmental magnetic investigations: Journal of Environmental & Engineering Geophysics, 1, 229–238
Analysis of the Euler method and its applicability in environmental magnetic investigations:Crossref | GoogleScholarGoogle Scholar |

Reid, A. B., Allsop, J. M., Granser, H., Millett, A. J., and Somerton, I. W., 1990, Magnetic interpretation in three dimensions using Euler deconvolution: Geophysics, 55, 80–91
Magnetic interpretation in three dimensions using Euler deconvolution:Crossref | GoogleScholarGoogle Scholar |

Roest, W. R., Verhoef, J., and Pilkington, M., 1992, Magnetic interpretation using the 3-D analytic signal: Geophysics, 57, 116–125
Magnetic interpretation using the 3-D analytic signal:Crossref | GoogleScholarGoogle Scholar |

Salem, A., and Ravat, D., 2003, A combined analytic signal and Euler method (AN-EUL) for automatic interpretation of magnetic data: Geophysics, 68, 1952–1961
A combined analytic signal and Euler method (AN-EUL) for automatic interpretation of magnetic data:Crossref | GoogleScholarGoogle Scholar |

Salem, A., William, S., Fairhead, D., Ravat, D., and Smith, R., 2007, Tilt-depth method: a simple depth estimation method using first-order magnetic derivatives: The Leading Edge, 26, 1502–1505
Tilt-depth method: a simple depth estimation method using first-order magnetic derivatives:Crossref | GoogleScholarGoogle Scholar |

Telford, W. M., Geldart, L. P., and Sheriff, R. E., 1990, Applied geophysics: Cambridge University Press.

Thompson, D. T., 1982, EULDPH: a new technique for making computer-assisted depth estimates from magnetic data: Geophysics, 47, 31–37
EULDPH: a new technique for making computer-assisted depth estimates from magnetic data:Crossref | GoogleScholarGoogle Scholar |

Thurston, J. B., and Smith, R. S., 1997, Automatic conversion of magnetic data to depth, dip, and susceptibility contrast using the SPI method: Geophysics, 62, 807–813
Automatic conversion of magnetic data to depth, dip, and susceptibility contrast using the SPI method:Crossref | GoogleScholarGoogle Scholar |

Verduzco, B., Fairhead, J. D., Green, C. M., and MacKenzie, C., 2004, New insights into magnetic derivatives for structural mapping: The Leading Edge, 23, 116–119
New insights into magnetic derivatives for structural mapping:Crossref | GoogleScholarGoogle Scholar |

Werner, S., 1953, Interpretation of magnetic anomalies at sheet-like bodies: Sveriges Geologiska Undersok, Series C, Arsbok 43, no. 6.

Wijns, C., Perez, C., and Kowalczyk, P., 2005, Theta map: edge detection in magnetic data: Geophysics, 70, 39–43