INTEGRATION AND JUXTAPOSITION OF EULER AND WERNER DECONVOLUTION TECHNIQUES FOR LITHO-STRUCTURAL CONTACT IDENTIFICATION AND MAGNETIC BASEMENT DEPTH DETERMINATION: A CASE STUDY OF ADO-EKITI, SOUTH-WEST NIGERIA

Telford, W. M., Geldart, I. P., and Sheriff, R. E. (1990). Applied Geophysics; 2nd Edn. 1006-10009.

Nabighian, M.N., Grauch, V.J.S., Hansen, R.O., Lafehr, T.R., Li, Y., Pierce, J.W., Phillips, J.D and Rander, M.E. (2005). The historical development of the magnetic method in exploration geophysics. Geophysics; 70(6): 33-61. https://doi.org.10.1190/1.21337841

Blakely, R.J. (1995). Potential theory in gravity and magnetic applications. Cambridge University Press. https://doi.org.10.1017/CNO9780511549816

Ghosh, G.K., Gupta, R.D., Khanna, A.K., and Singh, S.N. (2012). Application of EulerDeconvolution of Gravity and Magnetic Data for Basement Depth Estimation in Muzoram Area. Geohorizons; 1(3); 25-30.

Adetona, A., Abbas, A and Mallam, A. (2013). Estimating the Thickness of Sedimentation within the Lower Benue Basin and Upper Anambra Basin Nigeria using both Spectra Depth Deformation and Source Parameter Imaging. ISRN International Journal of Geophysics; 20(3): 112-117. https://doi.org.10.1155/2013/24706

Ndougsa-Mbarga, Yufenyiu, L.D., Quentin, Y.J and Tabod, C (2014). Delineation the Northern Limit of the Congo Craton Based on Spectral Analysis and 2.5D Modelling of Aeromagnetic Data in the Akonolinga-Mbama Area, Cameroon. Geofisica International; 53(1): 5-16.

Bikoro-Bi-Alou, M., Ndougsa-Mbarga, T., and Tabod, C. (2014). Quantitative Interpretation of Magnetic Anomalies in Ebolowa-Djoum Area (Southern Cameroon). Geophysica; 50(1): 11-25.

Ogunmola, J.K., Ayolabi, E.A., and Olobaniyi, S.B. (2016). Structural Depth Analysis of the Yola Arm of the Upper Benue Trough of Nigeria using High Resolution Aeromagnetic Data. Journal of African Earth Sciences. 124(1): 32-43. https://doi.org.10.1016/j.afrearsci.2016.09.008

Njoku, I. (2016). Magnetic Basement Depth Re-evaluation over the Yola Arm of the Upper Benue Trough, Nigeria from 3D Euler Deconvolution and Spectra Inversion of High Resolution Aeromagnetic Data. International Journal of Scientific and Engineering Research; 7(4): 223-228.

Ngoh, J.D., Ndougsa-Mbarga, T., Asembe, S.P., Meying, A., Owono-Amougwu, O.U.I and Tabod, C.T (2017). Evidence of Structural Facts Inferred from Aeromagnetic Data Analysis over the Guilder-Maroua Area, Northern Cameroon. Inter.Journal of Geosciences; 8(1): 781-800.

Yandjimain, J., Ndougsa-Mbarga, T., Meying, T., Bi-Alou, M.B, Ngoumou, P.C., Asembe, S.P., Ngoh, J and Owono-Amougou, O.U.I. (2017). Combination of Tilt-Angle and Euler Deconvolution Approaches to Determine Structural Features from Aeromagnetic Data Modelling over Akonolinga-Loum Area (Centre-East, Cameroon). International Journal of Geosciences; 8(1): 925-947. https://doi.org.10.4236/ijg.2017.87053

Mono, J., Ndougsa-Mbarga, T., Bi-Alou, M.B, Ngoh, J and Owono, Owono-Amougou, O.U.I. (2018). Inferring Subsurface Basement and the Contact Locations from Aeromagnetic Data over Loum-Minta Area (Centre-East Cameroon). International Journal of Geosciences; 9(1): 435-459. https://doi.org.10.4236/ijg.2018.97028

Nwankwo, L.I and Abayomi, J.S. (2017). Regional Estimation of Curie-point Depths and Succeeding Geothermal Parameters from Recently Acquired High Resolution Aeromagnetic Data of the Entire Bida Basin, North-Central Nigeria. Geothermal Energy Science; 5(1): 1-9.

Azab, A.A., Ramadan, M.A., and El-Sawy, M.I. (2019). An integrated Analysis of Gravity and Well Data for Deep-seated Structural Interpretation: a case study from Ras-Budran Oil field, Gulf of Suez, Egypt. Journal of Petroleum Exploration and Production Technology; 9(1): 177-189.

Ayomide, A., Felix., O.O., Adeboye, M.B. (2025). Deformation of Depth to Magnetic Sources from Aeromagnetic Data of Idah, Kogi State using Eulr Deconvolution Technique. International Journal of Earth Sciences, Knowledge and Applications; 7(2): 18-21.

Ukwuteyinor, U. B., Onwuemesi, A. G., Obiadi, I. I., Irumhe, E. P. and Osaghae, S.O. (2021). Estimation of depth to basement, heat flow and hydrocarbon potentials fromanalysis of aeromagnetic data in some parts of bida basin. Journal of Basic Physical Research 10 (1), January 2021

Njoku, J. O., Nwankwo, L. I., and Uche, E. I. (2022). Aeromagnetic evaluation of crustal structures in north-central Nigeria. International Journal of Earth Sciences; 76(4): pp. 210-225.

Opara, A.I., Emberga, T., Oparaku, O., Essien, A.G., Onyewuchi, R.A., Echetama, H.N., Muze, N.E., and Onwe, R.M. (2015). Magnetic Basement depth Re-evaluation of Naraguta and Environs, North-central Nigeria using 3D Euler Deconvolution. Exploration and Mining Journal. 3(32): 29-42. https://doi.org.10.12691/ajmm-3-2-1

Jekeli, C. (1985). On optimal Estimation of Gravity from Gravity Gradients at Aircraft Altitude. Revolution Geophysics; 23:301-311

Askaris, A. (2014). Edge Detection of Gravity Sources via the Tilt Angle Total Horizontal Derivative of the Tilt Angle and New Normalized Total horizontal Derivative. Scholars Journal of Engineering and Technology; 2(1): 842-846.

Zhou, W., Li, J., and Du, X. (2014). Semi-automatic Interpretation of Microgravity Data from the Subsurface Cavities using Curvature Gradient Tensor Matrix. Near Surface Geophysics; 125(5): 579-586. https://doi.org.10.10.3997/1873-0604.2014021

Arisoy, M.O and Dikmen, V. (2015). Edge Enhancement of Magnetic Data using Fractional –Order Derivative Filters. Geophysics; 80(1): 7-13.

Jayeoba, A and Odumade, D. (2015). Geological and Structural Interpretation of Ado-Ekiti Southwest and its Adjoining Areas using Aeromagnetic Data. Search and Discovery Article #30407 Extended Abstract from AAPG/SEG/SEPM Joint Technical Conference, Oxnard California. pp. 2-11.

Howari, F.M., Aldouri, R and Sadiq, A. (2016). Gravity Investigations of Recent Sinkholes and Karst Pits of Dahal Al-Haman, State of Qatar. Environmental Earth Science. 75(5): 440. https://doi.org.10.1007/su2665-016-5298-x

Abdelghany, O., Saima, M.A., Arman, H., and Fouler, A.R. (2017). Engineering Evaluation of Macrostructures in the Carbonate Rocks in Al-Ain Area, United Arab Emirates. International Conference on Engineering Geophysics, Al-Ain, United Arab Emirates. 9th-12th October, 2017. https://doi.org.10.1190/iceg2017.078

Murad, A and Gabir, A. (2017). Groundwater level Monitoring of the Quarternary Aquifer at Al-Ain City, United Arab Emirates using Geophysical Methods: In WSTA 12th Gulf Water Conference 28th to 30th March, 2017. Kingdom of Bahran Water in the GCC towards Integrated Strategies 70.

Aboud, E., El-Masry, N and Ahmed, S. (2018). Microgravity Mapping for King Abdul-Aziz University Campus: Imaging Subsurace. Arabian Journal of Geoscience. 11(2): 691. https://doi.org.10.1007/s12517-018-4029-x

Saibi, H., Hag, D.B., Alamri, M.S.M and Ali, H.A. (2021). Subsurface Structure Investigation of the United Arab Emirates using Gravity Data. Open Geoscience. 13(1): 262-271. https://doi.org.10.1515/geo-2020-0233

Zhang, M., Qiao, J., Zhao, G and Lan, X. (2019). Regional Gravity Survey and Application in Oil and Gas Exploration in China. China Geology. 2(3): 380-388. https://doi.org.10.31035/cg2018108

Okpoli, C.C and Akingboye, A.S. (2019). Application of High Resolution Aerogravity Data for Litho-structural and depth Characterization around Lgabi Area, Northwestern Nigeria. NRIAG Journal of Astronomy and Geophysics. 8(1): 231-241. https://doi.org.10.1080/20909977.2019.1689629

Pham, L.T., Oksum, E., and Do, T.D. (2019). Edge Enhancement of Potential Field Data using logistic Function and Total Horizontal Gradient. Acta Geodynamics and Geophysics; 54(1): 143-155.

Low, U., Absar, A., Duraiswami, R and Singh, A. (2020). Geophysical Exploration of Tura-Rajwadi Group of Hot Springs, West Coast Geothermal Province, Maharashtra, India and its Implications. Geothermics; 88(1): 652-665. https://doi.org.10.1016/j.geothermics.2020.101874

Pham, L.T., Eldosouky, A.M., Oksum, E., and Saada, S. (2020). A new High Resolution Filter for Source Edge Detection of Potential Field Data. GeoCarto International; 37(1): 3051-3068. https://doi.org.10.1080/10106049.2020.1849414

Mohammed, E.A., Pham, L.T., Mohammed, H., Pradhan, B.A. (2020). Comparative Study of THG, AS, TA, Theta, TDX and LTHG Techniques for Improving Source Boundaries Detection of Magnetic Data using Synthetic Models: A case study of from G-Um-mmquil North Eastern Desert Egypt. Journal of African Earth Science; 170(1): 521-532. https://doi.org.10.1016/j.jafrearsssci.2020.103940

Jacob, T., Pannet, P., Beaubois, F., Baltassant, J.M., and Hannion, Y. (2021). Cavity Detection using Microgravity in a highly Urbanized Setting: A case study from reins, France. Journal of Applied Geophysics; 179(1): 673-678. https://doi.org.10.1016/j.jappgeo.2020.140113

Melouah, O and Pham, L.T. (2021). An Improved ILTHG Method for Edge Enhancement of Geological Structures. Application to Gravity Data from the Qued Righ Valley. Journal of African Earth Sciences; 177(1): 6521-6534.

Porzucek, S and Loj, M. (2021a). Depth Estimation Problems in Microgravity Survey. Acta Geophysic;. 69(1): 665-672. https://doi.org.10.1007/s11600-021-00553-1

Mulugeta et al., 2021; Mulugeta, B.D., Fujimitsu, Y., Nishijima, J and Saibi, H. (2021). Interpretation of Gravity Data to Delineate the Subsurface Structures and reservoir Geometry of the Aluto-Langano Geothermal Field, Ethiopia. Geothermics; 94(1): 453-464. https://doi.org.10.1016/j.geothermics.2021.102093

Eldosouky, A.M., Pham, L.T., Henash, A. (2022). High Precision Structural Mapping using Edge Filters of Potential Field and Remote Sensing Data: A case Study from Wadi-Umon Ghalqa Area, South Eastern Desert, Egypt. The Egyptian Journal of Remote Sensing and Space Science; 25(2): 501-503. https://doi.org.10.1016/j.ejrs.2022.03.001

Prasad, K.N.D., Pham, L.T., and Singh, A.P. (2022a). Structural Mapping of Potential Field Sources using BHG Filter. Geocarto International; 37(26): 11253-11280.

Prasad, K.N.D., Pham, L.T., and Singh, A.P. (2022b). A novel filter ImTAHG for the Edge Detection and a case study from Cambay Rift Basin, India. Pure and Applied Geophysics; 179(6): 2351-2364.

Pham, L.T., Oksum, E., Kafadar, O., Trinh, D.T., Nguyen, D.V., Vo, Q.T., and Do, T.D. (2022a). Determination of Subsurface Lineaments in the Hoang Sa Islands using Enhanced Methods of Gravity Total Horizontal Gradient. Vietnam Journal of Earth Sciences; 44(3): 395-409.

Pham, L.T., Nguyen, T.U.Y., Xuan, E.W., Eldosouky, A.M., Do, T.D., and Nguyen, T.Q. (2022b). The Utility of the Enhancement Techniques for Mapping Subsurface Structures from Gravity Data. Frontier Science Research Technology; 3(1): 11-19.

Anthony, E.A., Likkasson, O.K., Maigari, A.S., Ali, S and Abubakar, A. (2023). Subsurface Structural Characterization as deduced from High Resolution Aeromagnetic Data over the Confluence Zones in Central Nigeria. Indonesian Journal of Earth Sciences; 3(1): 322-343. https://doi.org.10.52562/injoes.2023.600

Teknik, V and Ghods, A (2017). Depth of magnetic basement in Iran based on fractal spectral analysis of aeromagnetic data Geophys. J. Int. (2017) 209, 1878–1891

Pham, L.T. (2023). A Novel Approach for Enhancing Potential Fields: Application To Aeromagnetic Data of the Tuangiao, Vietnam. Europ Physical and Journal Plus; 138(12): 1-11.

Folorunsho, I., Magaji, Y., Ajadi, J., Issa, U. (2024). Application of Euler and Werner Deconvolution Techniques in Delineating Tin Deposit in Okeso Area, Southwestern Nigeria. Proceedings of the Nigerian Society of Physical Sciences; pp. 10-13. https://doi.org.10.61298/pnspsc.20241.96

Pham, L.T., Kemgang-Ghomsi, F.G., Eldosouky, A.M. (2025). Identification of the Structural Configuration of the Equitorial Atlantic Ridge from Satellite-derived Gravity Data using the Enhancement Techniques. Advances in Space Research; 75(2): 8425-8438. https://doi.org.10.1016/j.asr.2025.03.066

Kwega-Ghomsi, S.L., Bisso, D., Ganno, S., Pham, L.T., Tenzer, R., Kwega-Ghomsi, F.E. (2025). Reassessing Tectono-structural units and Crustal Thickness Variations in South-West Cameroon using Satellite Gravity and Seismic Data. Journal of African Earth Sciences; 229(1): 132-142. https://doi.org.10.1016/j.afrearsci.2025.105698

Ismail, F.F. and Saibi, H. (2025). A microgravity Investigation of the subsurface at the United Arab Emirates University Campus. Scientific Reports; 15(1): 225-232.

Ghosh, G.K. (2022b). Delineation of Major Subsurface Structural Features and Source Depth Locations using 3D Euler Deconvolution Gravity Data at Northeastern Part of India. Acta Geophysica; 70(1): 2033-2044. https://doi.org.10.1007/s11600-022-00829-0

Lasheen, E.S.R., Hassan, W., Eric, A., Azer, M.K. (2020). Implementation of Petrographical and Aeromagnetic Data to Determine Depth and Structural Trend of Homrit Waggart Area, Central Eastern Desert, Egypt. Applied Sciences; 12(17): 8782-8794. https://doi.org.10.3390/app12178782

Ayomide, A., Felix., O.O., Adeboye, M.B. (2025). Deformation of Depth to Magnetic Sources from Aeromagnetic Data of Idah, Kogi State using Eulr Deconvolution Technique. International Journal of Earth Sciences, Knowledge and Applications; 7(2): pp. 18

Raouf, A., Yue, J., Njeudjang, K., Tamehe, L.S., Onibudo, O.O. (2023). Remote Sensing and Geophysical Methods for Delineating Groundwater Resources in Schists hard rocks of the Adamawa Yade Domain, Cameroon. The Egyptian Journal of Remote Sensing and Space Science; 26(1): 217-230. https://doi.org.10.1016/j.ejrs.2023.02.006

Owona-Nanji, W.G., Meying, S., Nyouma, R.N., Edjo-Minko, R., Foudikou, O and Bessong, M. (2025). Combined analysis of Magnetic Investigations and Geological Mapping of Babouri-Figuil Basin (Northern Cameroon): Implications for Hydrocarbon Prospects. Geosystems and Geoenvironment; 5(1): 5561-5573. https://doi.org.10.1016/j.geogeo.2025.100437

Nekuye-Muafo, C.A., Basseka, C.A., Boum-Nkot, S.N., Som-Mbang, C.M., Njifeu-Tchoukewu, C.D., Kengne, Y.S., Tsopkeng, P.B., and Elame, J. (2018). Lineament Mapping in the Edea Area (Littoral Cameroon) using Remote Sensing and Gravimetric Data: Hydrogeological Implications. Journal of Applied Remote Sensing. 18(3): 2334-2348. https://doi.org.10.1117/1.jrs.18.032402

Kobe, E.B., Franck-Marcel, A.M., and Arsene, M. (2025). ResUMES++: Resistivity Uncertainty Modelling for Environmental Study. Journal of Applied Geophysics. 241 (1): 3342-3356. https://doi.org.10.1016/jappgeo.2025.105797

Opara, A.I., Emberga, T., Oparaku, O., Essien, A.G., Onyewuchi, R.A., Echetama, H.N., Muze, N.E., and Onwe, R.M. (2015). Magnetic Basement depth Re-evaluation of Naraguta and Environs, North-central Nigeria using 3D Euler Deconvolution. Exploration and Mining Journal. 3(32): 29-42. https://doi.org.10.12691/ajmm-3-2-1

Demirel, S., Alpar, B., Yalturak, C., Vardar, D., Kurt, H. (2020). Northern Segment of the North Anatolian Fault in the Gulf of Izmit Inferred from Marine Magnetic Anomalies. Marine Geophysical Research. 41(1):1-10.https://doi.org.10.10007/s11001-020-09399-6

Aktas, G., Hisarh, Z.M., and Demirel, A.S. (2021). High Resolution Total Field Magnetic Anomaly Maps of Lake Iznik North-West Turkey: Assessment of Faults which play Important Roles in Tectonics of Lake. Geophysical Research. 42(3): 1-17. https://doi.org.10.1007/s11001-021-09442-0

Hayatudeen, M., Bassey, N.E., Razaq, B. (2021). 2-D Modelling of High Resolution Aeromagnetic Data over Yola Arm of the Upper Benue Trough in Northern Nigeria. Global Journal of Pure and Applied Sciences. 27(2): 133-143. https://doi.org.10.4314/gjpas.v27i2.6

Vardar, D., Alp, H., Demrel, S., Aykurt, A., Vardat, H and Alpar, B. (2021). Offshore/Onshore Correlation of the North-Anatolian Fault Deformatons in the Wasuum Sea of M armara National Hazard. 107(2): 1905-1923. https://doi.org.10.1007/s11069-021-04664-2

Aktas, G., Hisarh, Z.M., and Demirel, A.S. (2022). Interpretation of the Tectonic Structure of Gemlik Bay using Magnetic Data. Tectonophysics. 863(1): 2231-2247.

Kiyak, A., Pamuk, E., Koksal, S., Bakar, M.L., Tosuner, S. (2022). New High Resolution Aeromagnetic Anomaly Map of Turkiye and its various Derivative-Based Maps. Turkish Journal of Earth Sciences. 32(2); 231-247. https://doi.org.10.55730/1300-0985.1840

Tarlowski, C., Gunn, P. J., & Mackey, T. (1997). Enhancements of the magnetic map of Australia. AGSO Journal of Australian Geology & Geophysics, 17(2), 77-82.

Agoha, C.C., Onwubuariri, C.N., Mgbeojedo, T.I., Amasike, C.U., Agbakwuru, C.B., Njoku, J.O., Akaolisa, C.C.Z., Alexander, O.I., Ofoh, I. (2023). Aeromagnetic Data Integration and Source Body Evaluation using Standard Euler deconvolution Technique in Obudu Area, Southeastern Nigeria. Petroleum and Coal; 65(4): 1033-1041.

Aktas, G. (2024). Edge Detection and Depth Estimation of Lake Sapanca, Eastern Marmara Region from High-Resolution Magnetic Data. Acta Geophysica (Applied Geophysics); 72(1): 3337-3354. https://doi.org.10.1007/s11600-023-01277-0

Opara, A.I., Emberga, T., Oparaku, O., Essien, A.G., Onyewuchi, R.A., Echetama, H.N., Muze, N.E., and Onwe, R.M. (2015). Magnetic Basement depth Re-evaluation of Naraguta and Environs, North-central Nigeria using 3D Euler Deconvolution. Exploration and Mining Journal; 3(32): 29-42. https://doi.org.10.12691/ajmm-3-2-1

Saleh et al. (2018). Azaiez, H., Gabtni, H., Bédir, M., and Campbell, S. (2018). Aeromagnetic study of buried basement structures and lineaments of the Sahel region (Eastern Tunisia, North Africa). Arabian Journal of Geosciences, 11, 140.

Roy, L., Chouteau, M., & Keating, P. (2000). Depth estimation of magnetic sources by an improved Euler deconvolution method. Journal of Applied Geophysics; 44(2-3), 183-199.

Phillips, C. V. Reeves, C. V. and Milligan, P. R. (2007). Aeromagnetic Surveys: Principle, Practice, and Interpretation. Geosoft ePublication; pp. 2321-2325

Kaukau, B., Greillingb, R.O., and Mzenti,. J.P. (2001). Pan-African Strike-Slip Tectonics in Eastern Cameroon Magnetic Fabrics (AMS) and Structure in the Lom Basin and its Gniessic Basement. Precambrian Research; 174(1): 258-272. https://doi.org.10.1016/j.precamres

. 2009.08.001

Kwekam, M., Liegeois, J.P., Njonfang, E., Affaton, P., Hartmann, G and Tohoua, F. (2010). Nature, Origin, and Significance of Formopoea Pan-African High CalciumAlkaline Plutonic Complex in the Central African Fold Belt (Cameroon). Journal of African Earth Sciences; 57(1): 79-95. https://doi.org.10.1016/j.jafrearsci

. 2009.07.012

Owona et al., 2011). Owona, S., Schulz, B., Patschbacher, L., Mvondo-Ondoa, J., Ekodeck, G.E., Tohoua, M.F., and Affaton, P. (2011). Pan-African Metamorphic Evolution in the Southern Yaounde Group (Oubanguide Complex, Cameroon) as revealed by EMD-Monazie Dating and Thermobarometry of Garnet Meta-pelites. Journal of African Earth Sciences; 59(1): 125-139. https://doi.org.10.1016/j.jafrearsci.2010.09.003

Florio, G and Fedi, M. (2013). Multiridge Euler Deconvolution. Geophysical Prospecting. 62(2): 148-163. https://doi.org.10.1111/1365-2478.12078

Porzucek, S and Loj, M. (2021). Microgravity Survey to Direct Voids and Loosening Zones in the Vicinity of the Mine Shaft. Energies; 14(1): 3021. https://doi.org.10.3390/en14113021

Olatunji, S and Adebisi, W. (2022). Werner Deconvolution Techniques for the Interpretation of Residual Aeromagnetic Anomalies of Igbeti Schist Belt: Implication for Marble Exploration. Indonesian Journal of Geosciences; 9(2): 209-217. https://doi.org.10.17014/ijog.9.2.209-217

Okwesili N.A, John, A.Y and Ossai N.M. (2025). Estimating the depth of basement rocks within the Guzabure and Gudumbali area of the Nigerian sector of the Chad basin using a spectral analysis technique. International Journal of Physical Sciences. 20(1): pp. 26-39.

Uieda, L., Souza-Junior, G.F., Uppal, I., Oliviera-Junior, V.C. (2025). Locating Sources of Potential Data through Inversion of Euler’s Inhomogeneity Equation. Earth-Arxiv, Geophysical Journal International; 241(3): 1536-1552.

Melo, F.F., Barbosa, V.C.F., Uieda, L., Oliviera, V.C., Silver, J.B.C. (2013). Estimating the Nature and the Horizontal and Vertical Positions of the 3D Magnetic Sources using Euler Deconvolution. Geophysics. 78(6): 187-198. https://doi.org.10.1190/geo2012-0515.1

Reid, A.B., and Thurston, J.B. (2014). The Structural Index is Gravity and Magnetic Interpretation: Errors, uses, and Abuses. Geophysics; 79(4): 161-166

Robinson, R.A.J., Brezina, C.A., Parish, R.R., Horstwood, M.S.A., Oo, N.W., Bird, M.I., Thein, M., Waters, A.S., Oliver, G.J.H., Zaro, K. (2014). Large Rivers and Origins: The Evolution of the Yarlung Tsangpo-Irrawaddy System and the Eastern Himalayas Syntaxis. Gondwana Research. 26(1): 2112-2121. https://doi.org.10.1016/j.qr2013.07.002

Ghosh, G.K. (2015). Interpretation of Gravity Anomaly and Crustal Thickness Mapping of Narmada-Sum Lineament in Central India. Journal of Geological Society of India; 86(3): 263-274. https://doi.org.10.1007/s12594-014-0077-3

Ghosh, G.K. (2016). Automatic Delineation of Structural Boundaries using Curvature Analysis of Bouguer Gravity Data in Parts of Northwest Himalaya. Journal of Geological Society of India; 91(5): 589-595. https://doi.org.10.1007/s12594-018-0909-7

Ghosh, G.K. (2019). Interpretation of Gravity Anomaly to Delineate Thrust Fault Locations at the Northeastern Part of India and its Adjacent Areas using Edge Detection Technique, Tilt Derivative and Cosθ Analysis. Acta Geophysica; 67(1): 1277-1295. https://doi.org.10.1007/s11600-019-00345-8

Ogbudu, P. A. Okon, E. E. Ugar, S. I. Lebo, S. E. Alo, G. A. and Okereke, C. S. (2025). Sediment thickness distribution and 2D depth model of the Ikom Basin, southeastern Nigeria, using high-resolution aeromagnetic data. Global Journal of Pure and Applied Sciences; 31(2): 211-227.

Mikołajczak M., Barmuta J., Ponikowska M., Mazur S. and Starzec K. (2021). Depth-to-basement study for the western Polish Outer Carpathians from three-dimensional joint inversion of gravity and magnetic data. Journal of Geosciences; 66 (1):15–36

Ndougsa-Mbarga, T., Feumo, N. S. A., Manguelle-Dicoum, E., & Fairhead, D. J. (2012). Aeromagnetic Data Interpretation to Locate Buried Faults in South-East Cameroon. Geophysica; 48(1-2), 49-63

Liozibhie, A.J., Ejepu, J.J., Szafarczyk, A., Agbasi, O.E., Inyang, N., and Egu, O.I. (2023). Retrospective Appurtenance of Euler and Werner Deconvolution Contiguity for Source Depth Excogitation of Bouguer Anomalies in Benue Trough, Nigeria. Journal of Sedimentary Environment; 8(3): 889-915. https://doi.org.10.1007/s43217-023-00146-7

Kominis, I. K., Kornack, T. W., Allred, J. C., and Romalis, M. V (2003). A subfemtotesla multichannel atomic magnetometer, Nature, Volume: 422, Issue 6932 Pages 596-599

Faruwa, A. R. Qian, W., Obafunmilayo, O. S. Daramola, B. B. Ali, M. A. H. Dusabemariya, C., and Markus, U. I. (2021). Airborne magnetic and radiometric mapping for lithostructural settings and its significance for bitumen mineralization over Agbabu bitumenbelt, southwestern Nigeria. Journal of African Earth Sciences; 180(1): 104222.

Eshanibli, A. S. Osagie, A. U. Ismail, N. A. and Ghanush, H. B. (2021). Analysis of gravity and aeromagnetic data to determine structural trend and basement depth beneath the Ajdabiya Trough in northeastern Libya. SN Applied Sciences, 3(2), Article 228.

Abbas M. I., Abdelhafeez T. H., Hamed T. A., and Rabeh T. (2024). Determining the Depth of Basement Surface and Subsurface Structures at Qarun Lake through Magnetic Data. Annals Geol. Surv. Egypt. XL (2024). pp. 97-108

Augie, A. I., Ibrahim, A. A., and Olagundoye, B. A., (2022). Aeromagnetic Data Analysis Using Improved Tilt Derivative Technique and 2D Modelling for Mineral Exploration in Parts of Northwestern Nigeria, Mining Science, 29: 179–203

Alexander, M. J., Pratsch, J. C., and Corine, P. (1998). Under the northern Gulf basin: basement depths and trends. In SEG Technical Program Expanded Abstracts. Society of Exploration Geophysicists; pp. 518–520.

Reid, A.B., Fitzgerald, F., and Mcinemy, P. (2003). Euler Deconvolution of Gravity Data. Society of Exploration Geophysics. SEG 2023 Conferences, Dallas. https://doi.org.10.13140/2.1.3210.0489

Xie, S and Tu, Z. (2015). Holistically-nested Edge Detection. In proceedings of the IEE International Conference on Computer Version, Santiago, Chile. 7th-13th October, 2015.

Xiong, W., Ji, X., Ma, Y., Wang, Y; AlBinHassan, N.M., Ali, M.N., and Luo, Y. (2018). Seismic Fault Detection Workflow with Convolutional Neural Network. Geophysics. 83(1): 97-103.

Zhao, T and Mukhopadhay, P. (2018). Fault Detection Workflow using Deep Learning and Image Processing. In Proceedings of the 2018. SEG International Exposition and Annual Meeting. Anahem, C.A. USA, 16th October, 2018. OnePetrol Richardsong, Texas, USA.

Dzukogi, A.N., Sanusi, Y.A., and Adeyinka, K.S. (2020). Euler Deconvolution and 2D Modelling of Subsurface Structures over Part of Northern Bida and its Surrounding Basement Rocks, North-West Nigeria using Magnetic Method. VIBGYOR International Journal of Earth Sciences and Geophysics. 6(2): 3427-3443. https://doi.org.10.35840/2631-5033/1838

; https://vibgyorpublications.org

Tang, Z., Wu, B., Wu, W and Maa, D. (2023). Fault Detection via 2.5D Transformer U-Net with Science Data Preprocessing. Remote Sensing Journal; 15(4): 1039-1049. https://doi.org.10.3390/rs15041039

Ishola, S.A and Ademulegun, M.A. (2025). Geological Charaterization and Depth to Basement Mapping of Magnetic Sources using High-Resolution Aeomagnetic Data: A Case Study of Ado-Ekiti and Environs (Sheet 244), South-West Nigeria. Unpublished Research Project. Department of Earth Sciences, Olabisi Onabanjo University Ago-Iwoye, South-West Nigeria. 1-131.

Omotoyinbo, Olusoji S. and Okafor, Francis C. (2008). Influence of Rock Mineralogy on Subsurface Water in Ado-Ekiti, Nigeria. African Research Review; 2(2): pp. 175-186

Ajakaiye, D. E. Hall, D. H. Ashiekaa, J. A. and Udensi, E. E. (1991). Magnetic anomalies in the Nigerian continental mass based on aeromagnetic surveys. Tectonophysics; 192(1–2): 211–230. https://doi.org/10.1016/0040-1951(91)90258-T

Ojo, O. J., and Omotose, S. O. (2008). Microfloral assemblage, age and palaeoenvironment of the Upper Cretaceous Patti Formation, Southeastern Bida basin, Nigeria. Journal of Mining and Geology; 44(1): 71-78

Ajibade, A. C., and Wright, J. B. (1989). The Togo-Benin-Nigeria Shield: Evidence of Crustal Aggregation in the Pan-African Belt. Tectonophysics; 165: 125-129

Ajayi, A. O., and Akintorinwa, O. J. (2015). Geoelectric investigation of a site for a proposed airport in Ebonyi State, Southeast Nigeria. FUDMA Journal of Sciences; 1(1), 315-320

Zhang, C., Mushayandebvu, M.F., Reid, A.B., Fairhead, J.D., and Odegard, M.E. (2000). Euler Deconvolution of Gravity Tensor Gradient Data. Geophysics; 65(2): 512-520

Hood, P. (1965). Gradient Measurements in Aeromagnetic Surveying. Geophysics. 30: 791-802

Thompson, D.T. (1982). EULDPH-A New Technique for Making Computer-Assisted Depth Estimates from Magnetic Data. Geophysics; 47: 31-37

Reid, A.B. (1995). Euler Deconvolution Past, Present, and Future, a Review: 65th Annual International Management Society of Exploration Geophysics; Expanded Abstracts. 272-273

Stanley, J.M and Green, R. (1976). Gravity Gradients and the Interpretation of the Truncation Plate: Geophysics; 41: 1370-1376

Wilsher, W.A. (1987). A structural Interpretation of the Witwatersrand Basin through the Application of Automated Depth Algorithms to both Gravity and Aeromagnetic Data: M.Sc Dissertation, University of Witwatersrand, South Africa

Corner, B and Wilsher, W.A. (1989). Structure of the Witwatersrand Basin Derived from the Interpretation of the Aeromagnetic and Gravity Data in Garland, G.D, Ed., Proceedings of Exploration ’87: Third Decennial International Conference on Geophysical and Geochemical Exploration for Minerals and Groundwater: Ontario Geol. Survey; Special Volume. 3: 532-546

Klingele, E.E., Marson, I., and Kahle, H.G. (1991). Automatic Interpretation of Gravity Gradiometric Data in two dimensions: Verti Grad: Geophysical Prospecting; 39(1): 407-434

Marson, I., and Klingele, E.E. (1993). Advantages of using the vertical gradient of Gravity for 3D Interpretation: Geophysics; 58: 1588-1595

Fairhead, J.D., Bennett, K.J., Gordon, R.H., and Huang, D. (1994). Euler: Beyond the Black Box: 64th Annual International Management Social Exploration Geophysics; Expanded Abstracts. 422-424

Huang, D., Gubbins, D., Clark, R.A., and Whaler, K.A. (1995). Combined Study of Euler’s Homogeneity Equation for Gravity and Magnetic Field: 57th Conference and Technical Exhibition. European Association of Exploration Geophysics; Extended Abstracts. 144

Mushayandebvu, M.F., Van-driel, P., Reid, A.B., and Fairhead, J.D. (2001). Magnetic source parameters of two-dimensional structures using extended Euler deconvolution. Geophysics; 66(1): pp. 814-823

Verduzco, B., Fairhead, J. D., Green, C. M. and MacKenzie, C. (2004). New insights into magnetic derivatives for structural mapping. The Leading Edge; 23(2): 116–119

Awoyemi, M.O., Arogundade, A.B., Falade, S.C., Ariyibi, E.A., Hammed, O.S., Alao, O.A and Onyedim, G.C. (2016). Investigation o Basement Fault Propagation in Chad Basin of Nigeria using High Resolution Aeromagnetic Data. Arabian Journal of Geosciences; 9(6): 453

Emujakporue, G., Ofoha, C.C., and Kiani, I. (2017). Investigation into the Basement morphology and Tectonic lineament using Aeromagnetic Anomalies of parts of Sokoto Basin, Northwestern Nigeria. Egyptian Journal of Petroleum; 27(4): 103. https://doi.org.10.1016/j.ejpe.2017.10.003

Adewumi, T. T., and Salako, K. A. (2017). Qualitative interpretation of aeromagnetic data for mineral potential assessment in Nasarawa State, north-central Nigeria. Nigerian Journal of Mining and Geology; 53(1): 45–58

Ekwueme, O.U., Obiora, D.N., Igwe, E.A., Abangwu, J.U. (2018). Study of Aeromagnetic Anomalies of Idah and Angba Areas, North-Central using High-Resolution Aeromagnetic Data. Modelling Earth Systems and Environment; 4(2): 461-474

Okpoli and Akingboye, 2019

Arogundade, A.B., Hammed, O.S., Awoyemi, M.O., Falade, S.C., Ajama, O.D., Olayode, F.A., Adebayo, A.S and Olabode, A.O. (2020). Analysis of Aeromagnetic Anomalies of Parts of Chad-Basin, Nigeria using High Resolution Aeromagnetic Data. Modeling Earth Systems and Environment; 6(3): 1545-1556

Salawu et al., 2020; Salawu, N. B. Orosun, M. M. Adebiyi, L. S. and Abdulraheem, T. Y. (2020). Existence of subsurface structures from aeromagnetic data interpretation of the crustal architecture around Ibi, Middle Benue, Nigeria. SN Applied Sciences; 2(3): Article 2230

Layade, G.O., Adewumi, O., Makinde, V and Bada, B. (2020). Estimation of Depth to Bouguer Anomaly Sources using Euler Deconvolution Techniques. RMZ-M & G2020. 671: 185-195. https://doi.org.10.2478/RMZM&G-2020-0016

Tawey, J. G., Olasehinde, P. I., Olorunfemi, M. O., and Akinluyi, F. O. (2020). Aeromagnetic investigation of subsurface structures and solid mineral potential in north-central Nigeria. Journal of African Earth Sciences; 168: 103845

Falufosi and Osinowo, 2021

Kahoul, S., Sidek, A., Eshanibli, A. S., Trepil, F., Jaafar, M. Z., Hassan, M., and Ghanoush, H. (2022). Identifying fault system and basement depth using aeromagnetic data beneath the Jahamah Platform, NE Sirt Basin, Libya. Acta Geodynamica et Geomaterialia, 19(2), 155–166

Akintoye, S.O., Adagunodo, T.A., Oladapo, M.I., Mimoh, E.A., Adebiyi, S.J., and Olayinka, A.I (2023). Many Gravity Maps over Nigeria including the Theoretical Gravity Map, Absolute Gravity Map and Bouguer Gravity Anomaly Map to the Geoid . Journal of Geophysics and Engineering; 20(3): 455-470. https://doi.org.10.1093/jge/gxac055

Edunjobi, S. O., Osinowo, O. O., and Adewumi, T. A. (2021). Estimation of Depth to Magnetic Basement in Ekiti State, Southwestern Nigeria from Aeromagnetic Data Using Spectral Analysis Technique. International Journal of Research and Innovation in Applied Science; 6(4): 1-7

Layade, G. O., Ajadi, J. A., Olatunji, S., and Imoukhuede, O. B. (2023). Use of Airborne Radiometric Data for Bitumen Exploration in Agbabu Area, Southwestern, Nigeria. IOSR Journal of Environmental Science, Toxicology and Food Technology, 12(2), 09-15

Layade, G.O., Edunjobi, H.O, and Ajayi, K.D. (2024). Lineament Qualitative Interpretation and Depth Evaluation of Potential Field Signatures in the Abeokuta Region, Southwestern Nigeria. Journal of the Earth and Space Physics; 49(4): 231-239

Ishola, S.A and Ademulegun, M.A. (2025). Geological Characterizations and Depth to Basement Mapping of Magnetic Sources using High-Resolution Aeromagnetic Data: A Case Study of Ado-Ekiti and Environs (Sheet 244), South-West Nigeria. Unpublished B.Sc Degree Project, Department of Geology, Olabisi Onabanjo University, Ago-Iwoye. pp. 14-17

Babylon, O.B. (2019). Tectonic and structural analysis of the migmatitic gneiss-quartzite complex of Ilorin area from aeromagnetic data. NRIAG Journal of Astronomy and Geophysics; 8(1): pp. 22-23. https://doi.org.10.1080/20909977.2019.1615795

El-Bohoty, M., Khalil, A., Hussain, W., El-kotb, A., Awad, A., and Khalifa, M. (2021). Geophysical studies of subsurface structures of the area surrounding the new part of Jarjob in El-Negila-Massa Matruh using magnetic data. NRIAG Journal of Astronomy and Geophysics; 10(1): pp. 456-471. https://doi.org.10.1080/20900977.2021.1907963

Nagy, D. (1966). The Gravitational Attraction of a Right Rectangular Prism. Geophysics; 31: 362-371

Nagy and Fury (1990). Nagy, D. and Fury, R.J (1990). Local Geoid Computations from Gravity using the Fast Fourier Transform Technique: B. Geodesique. 64: 283-294

Forsberg, R. (1984). A study of Terrain Reductions, Density Anomalies and Geophysical Inverse Methods in Gravity Field Models. Department of Geodetic Science and Surveying Report; Ohio State University. Report 355

Ekwok, S.E., Achadu, O.M., Akpan, A.E., Eldosouky, A.M., Ufuafuonye, C.H., Abdelrahman, K., and Gomez-Ortiz, D. (2022). Depth estimation and basement rocks in the Bornu Basin, North-West Nigeria using High Resolution Airborne Magnetic Data. MDDP Minerals; 12(3): pp. 445-462. https://doi.org.10.3390/min12030285285

Steenland, N.C. (1968). Discussionon the Geomagnetic Gradiometer by H.A Slack, V.M. Lynch, and L.Langan (Geophysics, 1967, 877-892). Geophysics 33:680-683

Barnett, C.T. (1976). Theoretical modeling of the magnetic and gravitational fields of an arbitrarily shaped three-dimensional body. Geophysics; 41:1353-1364

Schwarz, K.P., Sideris, M.G., and Forsberg, R. (1990). The use of FFT Techniques in Physical Geodesy: Geophysical Journal International; 100: 485-514

Zhang, C. and Sideris, M.G (1996). Ocean Gravity by Analytical Inversion of Hotine’s Formula.Marine Geodesy. 9: 115-136

Zhang, C. (1995). A General Formula for Gravimetric Transformations by the use of Convolution and Deconvolution Techniques. Journal of Geodesy. 70: 51-64

Werner, S. (1953). Interpretation of Magnetic Anomalies of Sheet like Bodies. Sveriges Geologist Under SerC.C, Arabok. 43(6): 4-7

Srivatava, R.P. (2004). Determination of Magnetic Basement using Werner Deconvolution. 5TH Conference and Exposition on Petroleum Geophysics, Hyderabad, 2004. India. Pp. 953-956

Hartman, D.R., Teskey, D.J and Preidberg, J.L. (1971). A system for Rapid Digital Aeromagnetic Interpretation. Geophysics; 36(5): 891-918

Jain, 1976

Ku, C.C and Sharp, J.A. (1983). Werner Deconvolution for Automatic Magnetic Interpretation and its Refinement using Marquardt’s Inverse Modeling. Geophysics; 48(6): 754-774

Malleswara-Rao, M.M., Lakshminarayana, S., Murthy, K.S.R and Subrahmanyam, A.S. (1993). Two ComputerPrograms for the Analysis of Marine Magnetic Data. Computer and Geosciences. 19(5): 657-672

Sarma, K.V.L.S., Ramana, M.N., Murthy, G.P.S., Subrahmanyam, V., Krishna, K.S., Chaubey, A.K., Mallaswara-Rao, M.M and Narayana, S.L. (1994). Application of Inversion Techniques on Marine Magnetic Data-Andaman Shelf, Journal of Geological Society of India; 44(1): 73-78

Thakur, N.K., Gangadhara-Rao, T., Ramesh-Khanna and Subrahmanyam, C. (2000). Magnetic Basement in the Bay of Bengal through Werner Deconvolution. Marine Geology; 162: 599-605

Martins, O.E., Mosto, O.K., and Ifeanyi, O.A. (2021). Aeromagnetic interpretation of basement structure and architecture of the Dahomey basin, Southwestern Nigeria. NRIAG Journal of Astronomy and Geophysics; 10(1): pp. 93-109. https://doi.org.10.1080/2099977.2021.1880817

Radhakrishna-Murthy, I.V., Swamy, K.V., and Rama-Rao, P. (2000). Use and Abuse of Werner deconvoluion Technique. Journal of India Geophysical Union; 4(2): 97-102

Rao, B.S.R., Radhakrishna-Murthy, I.V. and Visweswara-Rao, C. (1973). A Direct Method of Interpreting Gravity and Magnetic Anomalies: The case of a Horizontal Cylinder, PAGEOPH. 102(11): 67-72

Sudhakar, K.S., Rao, P.R and Radhakrishna-Murthy, I.V. (2004). Journal of India Geophysical Union; 8(3): 179-183

Radhakrishna-Murthy, I.V. (1998). Gravity and Magnetic Interpretation in Exploration Geophysics. Geological Society of India, Banglore, India

Keating, P. (1995). A simple technique to identify magnetic anomalies due to Kimberlie pipes: exploration. Mining Geology; 4(1): pp. 121-125

Sylvester, E. E., Okpoli, E., & Oladejo, O. P. (2018). Interpretation of aeromagnetic data over some parts of Mambilla Plateau, Taraba State. International Journal of Physical Sciences, 13(4), 33-42

Edunjobi, H.O., Layade, O.G., Makinde, V., Bada, B.S., Ogunbayo, A.F., and Atunrase, K.A. (2023). Qualitative Interpretation of High Resolution Aeromagnetic Data of Abeokuta Metropolis for Geological Characterization. Results in Geophysical Sciences. 15(1): 101-128

NGSA. (2005). Nigerian Geological Survey Agency. Airborne Geophysical Digital Data Dissemination Guidelines. 22-25

NGSA. (2005). Nigerian Geological Survey Agency. High-Resolution Airborne Geophysical Survey. NGSA Bulletin. pp. 16

Tsokas, G.N and Papazachos, C.B (1992). Two-dimensional inversion fitters in magnetic prospecting: Application to the exploration for buried antiquities. Geophysics; 57(1): pp. 1004-1013. https://doi.org.10.1190/1825939

Arekumo, T. (2023). Applying Geophysical Method for Investigation of the Depth of the Mineralization Potential of Ikogosi and Environs Using Aeromagnetic Data. World Scientific News; 184: 75-88

El-Dawn, M.G., Tianyouw, L., Hui, S., and Dopeng, L. (2004). Depth estimation of 2D magnetic anomaly sources by using Euler deconvolution method. American Journal of Applied Science; 1(3): pp. 209-214. https://doi.org.10.3844/ajassp.2004.209.214

Ogah, A.J and Abubakar, F. (2024). Solid Mineral Potential Evaluation using Integrated Aeromagnetic and Aeroradiometric Datasets. Scientific Reports; 14(1): 167. https://doi.org.10.1038/s41598-024-52270-6

Okpoli, C.C and Oladunjoye, M.A (2017). Precambrian Basement Architecture and Lineaments Mapping of Ado-Ekiti Region using Aeromagnetic Dataset. Geosciences Research. 2(1): 27-45. https://doi.org.10.22606/gr.2017.21005

Ostrowski, J. A., Pilkington, M., and Morris, W. A. (1993). Werner deconvolution for variable altitude aeromagnetic data. Geophysics, 58(10), 1481-1490