Spontaneous Frequency Polarisation (SFP) method application for mapping mineral deposits in the metamorphic sedimentary formations in the Bidzar area (North-Cameroon)

Volume 6, Issue 1, February 2022     |     PP. 1-22      |     PDF (3393 K)    |     Pub. Date: February 24, 2022
DOI: 10.54647/geosciences17152    85 Downloads     89558 Views  

Author(s)

Daniel Hervé Gouet, Department of Mines, Oil, Gas and Water Resources Exploration, Faculty of Mines and Petroleum Industries, University of Maroua, P.O. Box 08 Kaélé, Far North – Cameroon
Marcelin Bikoro Bialou, Department of Earth Sciences, Faculty of Science, University of Maroua, P.O. Box 46 Maroua, Cameroun
Arsène Meying, Department of Applied Geophysics, School of Geology and Mining Engineering, University of Ngaoundere, P.O. Box 115 Meiganga, Cameroon

Abstract
The North Cameroon (Central Africa) region rests on Precambrian metamorphic rocks dating. In the areas covered by metamorphic sedimentary formations, this region conceals a significant mineral potential. The geological and geochemical works carried out in the study area permitted to analyze the mineralogy of the formations in place and to map the formations with good potential in useful minerals. This work, using the hammer prospecting technique, mapped the marble identified as the local commodity. A geophysical study using the Electro-Telluric or Spontaneous Frequency Polarization (SFP) method was carried out to evaluate the electrical parameters of the surface formations, particularly those of the ore in the Bidzar area. This study is based on a set of fifty-five (55) profiles, NW-SE direction, inter-profile distance one hundred (100) meters and length varying between 1 km and 2.2 km. The geophysical surveys are carried out at a step of fifty (50) meters using a PQWT500 geoelectrical device from the Hunan Puqi Institute (China). The results of this study show that the Bidzar marble ore is a network of lenticular corridors trending NE-SW. These corridors are mainly characterized by high electrical gradients (ddp > 3mV). They alternate with schist or sterile rocks of relatively low electrical gradients (ddp < 3 mV). The comparison of the above-mentioned results with the geological results of hammer prospecting and the borehole data show a perfect correlation of the electrical responses (ddp) with the geological formations in place. Thus, it confirms the validity of the spontaneous frequency polarization (SFP) method in the mapping of ores from metasedimentary formations, particularly those of the marble type.

Keywords
Electro-telluric, cartography, marble, electric gradient, lenticular corridors

Cite this paper
Daniel Hervé Gouet, Marcelin Bikoro Bialou, Arsène Meying, Spontaneous Frequency Polarisation (SFP) method application for mapping mineral deposits in the metamorphic sedimentary formations in the Bidzar area (North-Cameroon) , SCIREA Journal of Geosciences. Volume 6, Issue 1, February 2022 | PP. 1-22. 10.54647/geosciences17152

References

[ 1 ] Telford, W. M., Geldart, L. P., Sheriff, R. E., Keys, D. A. (1990) Applied geophysics 2th edition, Cambridge University press, 770 p.
[ 2 ] Toteu, S. F, Van Schmus, W. F., Penaye J. P. and Michard A. (2001) New U-Pb and Sm-Nd data from north-central Cameroon and its bearing on the pre-Pan-African history of central Africa, Precambrian Res. 108, pp. 45–73.
[ 3 ] Ndjeng, E. (1998) Les structures sédimentaires du bassin de Babouri-Figuil (fossé de la Bénoué) dans le Nord-Cameroun. Géosciences au Cameroun, Vicat J.P. et Bilong P. éd., collect. GEOCAM, Press. Univ. Yaoundé I., pp. 149-156.
[ 4 ] Ngounouno, B. Déruelle, R. Guiraud, J. P. and Vicat, (2001) Magmatismes tholéiitique et alcalin des demi-grabens crétacés de Mayo Oulo-Léré et de Babouri-Figuil (Nord du Cameroun–Sud du Tchad) en domaine d’extension continentale, C. R. Acad. Sci.Paris, Ser. IIa 333 (2001) PP 201–207.
[ 5 ] Dawaï, D. (2014) Les plutons de Guider et de Bossoum-Pologozom (chaîne panafricaine au Nord-Cameroun) : analyses pétrographique, structurale, magnétique, géochronologique et implications géodynamiques. Thèse de Doctorat, Page 195.
[ 6 ] Vallerie, M., (1964). Feuilles Bidzar et Guider Ed 1964 p. (10-11)
[ 7 ] Keary, P. and Brooks, M. (1991). An Introduction to Geophysical Exploration. Blackwell Scientific Publications, 2nd ed, 254 p.
[ 8 ] PQWT publications, videos (http://www.pqwtcs.com/NewsDetail.aspx?nid =3643&classid =273) & website http://www.pqwtcs.com/.
[ 9 ] Das, U.C. and Verma, S. K. (1980) Digital Linear Filter for Computing Type Curves for the Two-Electrode System of Resistivity Sounding, Geophysical Prospecting 28, 610-619.
[ 10 ] Koefoed, O. (1970). A fast method for determining the layer distribution from the raised kernel function in geoelegtrical sounding. Geophysical Prospecting, 18(4), 564–570. doi:10.1111/j.1365-2478.1970.tb02129x
[ 11 ] Koefoed, O. (1979) Resistivity Sounding Measurements, Ser. Methods in Geochemistry and Geophysics 14A, Geosounding Principles 1. Elsevier, Amsterdam Oxford-New York, 276 p
[ 12 ] Zagarmistr, A. M. and Berdichevskiy, M. N. (1959). Electrical prospecting by the telluric currents method. Petroleum Geology: A digest of Russian literature on Petroleum Geology, Vol. 3, No. 1B., pp. 40-49
[ 13 ] Liao X, Cheng H and Bai Y, (2012). Design and Application of Natural Audio Electric Field Frequency Selecting Instrument. Applied Mechanics and Materials Vol. 103, pp 15-19.
[ 14 ] Cheng H., Di Q. Y. and Li D. Q. (2010) The discussion electrical properties of rocks base on frequency characteristics. Progress in Geophy. (In Chinese), 25(3): 918-925.
[ 15 ] Dorbath, C. (1979) Prospection géophysique des cipolins de bandafassi (sénégal oriental). ORSTOM, Géophys., no 16: 35-46.
[ 16 ] Palacky, G. J. (1989) Resistivity characteristics of geologic targets, In MN Nabighian, Ed, electromagnetic methods in Applied Geophysics, vol. 1 (theory) IG, No 3, Society of Exploration Geophysics, pp. 53-129.