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In this study, digital format data comprising of aeromagnetic and remotely sensed (Landsat ETM+7) data were used for structural interpretation of the Awgu area (predominantly underlain by sedimentary rocks) in Enugu State, southeastern part of Nigeria. Aeromagnetic data were analyzed using the Oasis Montaj 7.5 software and interpretation was carried out by applying the vertical and horizontal gradients, analytical signal, reduction to pole, tilt depth, as well as Euler deconvolution. The total magnetic intensity map shows a magnetic signature ranging from -39nT to 129nT. The 3D Euler solution of the study area has a structural index of 1.0 with dyke/fault as the shape of the inferred geological structure. In the Landsat ETM+7 satellite data used, band 5 was found as the most suitable in (automatic) delineation. The automatic lineament extraction process was carried out utilizing the line module of PCI Geomatica (2015 version). The essence of analysis and interpretation of the Landsat ETM+7 was to determine the lineament trends and density across the area. Rockworks 16 version software was used to generate the rose diagrams. As a result of the work, the aeromagnetic and Landsat lineament maps of the study area were summarized using rose diagrams. This revealed NESW as the major trend with some secondary trends NW-SE, E-W and N-S directions. However, the NE-SW trend reflects the younger tectonic events, because the younger events are more pronounced and tend to obliterate the older events. In a comparison of the aeromagnetic and Landsat lineament extraction of the study area in terms of number of lineaments, directions and total length of lineaments, the Landsat imagery were found to be better than the number, directions and total length of the aeromagnetic data.
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p.79-105,fig.,ref.
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- Department of Physics, College of Physical and Applied Sciences, Michael Okpara University of Agriculture, Umudike, Nigeria
autor
- Department of Physics, College of Physical and Applied Sciences, Michael Okpara University of Agriculture, Umudike, Nigeria
autor
- Department of Physics, College of Physical and Applied Sciences, Michael Okpara University of Agriculture, Umudike, Nigeria
Bibliografia
- [1] Ananaba, S.E. (1991). Dam sites and crustal megalineaments in Nigeria. ICT Journal 1: 26-29.
- [2] Attoh, K., Brown, L.D. (2008). The Neoproterozoic Trans-Saharan/Trans-Brasiliano shear Zones: Suggested Tibetan Analogs. American Geophysical Union.
- [3] Beamish, D. (2012). The application of spatial derivatives to non-potential field data Interpretation. Geophysical Prospecting. 60, 337-360.
- [4] Blakely, R.J. (1995). Potential theory in gravity and magnetic applications. Cambridge University Press, Australia. 6: 116-139.
- [5] Burger R.H., Sheehan, A.F., Jones, C.H. (2006). Introduction to Applied Geophysics Published by W.W. Norton. 600 pages.
- [6] David, L.C. and Oliver N.M. (1998). Aeromagnetic demonstration survey with basement Interpretation and deep structure mapping. Final report prepared for the New York State Energy Research and Development Authority. 1-20.
- [7] Grauch, V. J. S. and Johnston, C. A. (2002). Gradient window method: A simple way to Separate regional from local horizontal gradients in gridded potential-field data, 2002 Technical Program Expanded Abstracts, 72nd Annual Meeting, Society of Exploration Geophysicists 762-765.
- [8] Gunn P.J. (1975). Linear transformation of gravity and magnetic fields. Geophysical Prospecting 23(2). 300-312.
- [9] Gunn, P.J., Maidment D. and Milligan, P.R. (1997). Interpreting aeromagnetic data in areas of limited outcrop. AGSO Journal of Australian geology and geophysics 17(2), 175-185.
- [10] Hani A., Nezar, H., Mohammed, A., Elias, S., Abdullah, D., Mohammed, H. and Rida, A. (2013). Integration of aeromagnetic data and landsat imagery for structural analysis purposes: A case study in the southern part of Jordan. Journal of geographic information system. 5, 198-207.
- [11] John, M.U. and Emmanuel U.E. (2014). Structural analysis using aeromagnetic data: Case study of parts of southern Bida basin, Nigeria and the surrounding basement rocks. Earth Science Research. 3(2), 27-42.
- [12] Labbo, A.Z. and Ugodulunwa F.X.O. (2007). An interpretation of total intensity aeromagnetic maps of part of southeastern Sokoto basin. Journal of engineering and applied sciences 3; 15-20.
- [13] Madani, A.A (2001). Selection of the optimum landsat thematic mapper bands for automatic lineaments extraction, Wadi Natash area, Southeastern desert, Egypt. Asian Journal of Geoinformatics. 3(1), 71-76.
- [14] O’Leary, D.W., Friedman J.D., and Phn, H.A. (1976). Lineament, Linear, Lineation: Some proposed new standards for old terms. Geology Society American Bulletin 87: 1463-1469.
- [15] Olowofela, J.A., Akinyemi, O.D., Idowu, O.A., Olurin, O.T and Ganiyu S.A. (2012). Estimation of Magnetic Basement Depths beneath the Abeokuta Area, South west Nigeria from Aeromagnetic Data using Power Spectrum. Asian Journal of Earth Sciences 5(2), 70-78.
- [16] Onyewuchi, R.A, Opara, A.I, Ahiarakwa, C.A and Oko, F.U. (2012). Geological Interptretations inferred from airborne magnetic and landsat data: Case study of Nkalagu area, southeastern, Nigeria. International journal of science and technology 2 (4), 178-191.
- [17] Opara, A.I., Ugwu, S.A. and Onyewuchi R.A. (2012). Structural and tectonic interpretations from landsat 5 thematic imagery: case study of Okposi brine lake and environs, lower Benue trough, Nigeria. Elixir Remote Sensing 49, 9708-9713.
- [18] Phillips, J. D. and Grauch, V. J. S. (2001). Some current research on the processing and interpretation of potential-field data at the U.S. Geological Survey, in Workshop on future directions in the analysis of potential-field data, August 18, 2001, Perth, Australia.
- [19] Raimi, J., Dewu, B.B.M, Sule, P. (2014). An interpretation of structures from the Aeromagnetic field over a region in the Nigerian younger granite province. International journal of geosciences 5, 313-323.
- [20] Salem, A., Williams, S., Fairhead, J.D., Smith, R., and Ravat, D. (2007). Tilt-depth method: A simple depth estimation method using first-order magnetic derivatives. The Leading Edge, 26(12), 1502-1505.
- [21] Sultan, A.S.A and Josef, P. (2014). Delineating groundwater Aquifer and subsurface structures using Integrated Geophysical interpretation at the Western part of Gulf of Aqaba, Sinai, Egypt. International Journal of Water Resources and Arid Environments 3(1), 51-62.
- [22] Suzen, M.L and Toprak, V. (1998). Filtering of satellite images in geological lineament analyses: An application to a fault zone in Central Turkey. International journal of remote sensing 19(6), 1101-1114.
- [23] D G A Whitten with J R V Brooks (1972). The Penguin dictionary of Geology. Published by Allen Lane, London.
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