Depth and Structural Parameters Determination of the Sedimentary Basin in Atmur Nuqra Area, South Eastern Desert, Egypt Using Aeromagnetic Data Analysis
The study area is located at the south of the eastern desert of Egypt between latitudes 24°N to 25°N and longitudes 33°E to 33°50'E covering an area of about 9407 km2. The study area is mainly covered with sediments whose age extends from the upper Cretaceous to the Quaternary, in addition to the presence of some basement rocks such as younger granites, metasediments and metagabbro. The research aims essentially to determine the thickness of the sedimentary basin by determining the depth to the top of basement and delineating the subsurface geological structures which affected this sedimentary basin. The Euler depth map exhibited that the north parts of the area have shallow depth values from 1000 m to 2000 m. The southern parts also show a shallow to moderate depths ranging from 1000 m to 2400 m. The deepest parts are located at the middle and at the western parts and are ranging in value from 3000 m to more than 4000 m. The horizontal derivative and tilt derivative techniques proved that the most effective trends all over the study area are NW-SE and NE-SW directions as mentioned in geologic lineaments map. The basement tectonic map shows clearly all the faults affected the area. It shows that there are many high blocks trending mainly in NW-SE and NE-SW directions. All high blocks surround a large sedimentary basin reaches depth of about more than 4000 m. All the results produced from 2D-modeling illustrate that the sedimentary basinal area (G2) is the deeper basin all over the area and it is controlled by some faults and fractures. 3D inversion was used and resulted in that the area of study have many high blocks at shallow to moderate depths which surrounding a large sedimentary basinal area with very deep depth values. All the techniques which applied in this research led to that the largest sedimentary basin is located at the center of the study area with NW-SE trend and depth value of about 4000 m.
References
[1]
Shackleton, R.M., Ries, A.C., Graham, R.H. and Fitches, W.R. (1980) Late Precambrian Ophiolitic Mélange in the Eastern Desert of Egypt. Nature, 285, 472-474.
https://doi.org/10.1038/285472a0
[2]
Said, R. (1962) Geology of Egypt. Elsevier Publ. Co., Amsterdam and New York, 293-319.
[3]
El-Gaby, S. (1983) Architecture of the Egyptian Basement Complex. Proceedings of the Fifth International Conference on Basement Tectonics, Cairo.
[4]
El-Ramly, M.F., Greiling, R.O., Kroner, A. and Rashwan, A. (1984) On the Tectonic Evolution of Wadi Hafafit Area and Environs, Eastern Desert of Egypt. In: Al-Shanti, A.M., Ed., Proceedings of a Symposium on Pan-African Crustal Evolution in the Arabian Shield, I. G. C. P. No. 164.
[5]
Krőner, A. (1984) Ophiolites and Evolution of Tectonic Boundaries in the Late Proterozoic Arabian-Nubian Shield of Northeast Africa and Arabia. Precambrian Research, 27, 277-300. https://doi.org/10.1016/0301-9268(85)90016-6
[6]
El-Bayoumi, R.M.A. and Greiling, R. (1984) Tectonic Evolution of a Pan-African Plate Margin in Southeastern Egypt—A Suture Zone Overprinted by Low Angle Thrusting. J. Afric. Geol, 47-56.
[7]
Ries, A.C., Shackleton, R.M., Graham, R.H. and Fitches, W.R. (1983) Pan-African Structures, Ophiolites, and Mélange in the Eastern Desert of Egypt: A Traverse at 26° N. Journal of the Geological Society, 14, 75-95.
https://doi.org/10.1144/gsjgs.140.1.0075
[8]
Habeib, M.S., Ahmed, A.A. and El-Nady, O.M. (1985) Two Orogenies in the Meatiq Area of Central Eastern Desert, Egypt. Precambrian Research, 30, 83-111.
https://doi.org/10.1016/0301-9268(85)90047-6
[9]
Conco Coral and EGPC (1987) Geological Map of Egypt, Scale 1:500,000.
[10]
Aero-Service (1984) Final Operational Report of Airborne Magnetic/Radiation Survey in the Eastern Desert, Egypt. For the Egyptian General Petroleum Corporation (EGPC) and the Egyptian Geological Survey and Mining Authority (EGSMA), Aero-Service Division, Houston, Six Volumes. https://doi.org/10.1190/1.1441278
[11]
Thompson, D.T. (1982) “EULDPH”: A New Technique for Making Computer-Assisted Depth Estimates from Magnetic Data. Geophysics, 47, 31-37.
https://doi.org/10.1190/1.1442774
[12]
Reid, A.B., Allsop, J.M., Granser, H., Millet, A.J. and Somerton, I.W. (1990) Magnetic Interpretation. Geophysics, 55, 80-91.
[13]
Geosoft Inc. (2010) Geosoft Mapping and Processing System. Geosoft Inc., Toronto.
[14]
Parker, R.L. (1972) Inverse Theory with Grossly Inadequate Data. Geophysical Journal International, 29, 123-138.
https://doi.org/10.1111/j.1365-246X.1972.tb02203.x
