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dc.contributor.authorTematio, P.
dc.contributor.authorSongmene, S.M.
dc.contributor.authorLeumbe, O.L.
dc.contributor.authorNouazi, M.M.
dc.contributor.authorYemefack, M.
dc.contributor.authorFouateu, R.Y.
dc.date.accessioned2019-12-04T10:58:01Z
dc.date.available2019-12-04T10:58:01Z
dc.date.issued2015
dc.identifier.citationTematio, P., Songmene, S.M., Leumbe, O.L., Nouazi, M.M., Yemefack, M., & Fouateu, R.Y. (2015). Mapping bauxite indices using Landsat ETM+ imageries constrained with environmental factors in Foumban area (West Cameroon). Journal of African Earth Sciences.
dc.identifier.issn1464-343X
dc.identifier.urihttps://hdl.handle.net/20.500.12478/895
dc.description.abstractThe present study aims at mapping some western Cameroon bauxites combining results of digital processing of satellite data (ETM+ of LandSat) with the geological, structural, mineralogical and geochemical characteristics of the Foumban area. Two categories of encrusted bauxitic surfaces have been identified: (i) discontinuous surfaces covering a total area of 11.13 km2, and (ii) continuous surfaces overlapping 2.41 km2. Field observations portray discontinuous surfaces with 5.5 m thick bauxitic mantle subdivided into 1.5 m thick discontinuous duricrust lying on 4.0 m thick continuous duricrust. The continuous surfaces are 4.1 m thick bauxitic duricrust. Mineralogical studies showed that the Foumban bauxites exhibit 78–86% of gibbsite, 7–22% of goethite and less than 7% of kaolinite. Geochemically, Al is the most abundant element with 45.6–58.7 wt.% of Al2O3; followed by Fe with 12.9–20.1 wt.% of Fe2O3 and Si with 1.0–3.7 wt.% of SiO2. Element mobility stated with enrichment factor (EF) allows differentiating three chemical elements: strongly depleted with EF < 1 (Si, Ca, Mg, K, Na, Cu, Mn, Zn); strictly enriched with EF > 1 (Al, Fe, Cr); and with irregular depletion and enrichment behavior with EF ± 1 (Nb, Sr, V, Zr). Based on mass-transport function (M), elements decrease as follows: Sr > Nb > Cr > Al > Zr > V > Zn > Fe > Cu > Si > Ca > K = Na > Mg > Mn. The Foumban encrusted bauxites are classified as laterite and iron-rich high grade orth-bauxites with 45.6–58.7 wt.% of Al2O3 and 1.0– 3.7 wt.% of SiO2, with bauxite reserves estimated to 75.8 million tons. The mapping approach has shown to be suitable for delineating encrusted bauxitic surfaces within loose laterites in tropical regions.The present study aims at mapping some western Cameroon bauxites combining results of digital processing of satellite data (ETM+ of LandSat) with the geological, structural, mineralogical and geochemical characteristics of the Foumban area. Two categories of encrusted bauxitic surfaces have been identified: (i) discontinuous surfaces covering a total area of 11.13 km2, and (ii) continuous surfaces overlapping 2.41 km2. Field observations portray discontinuous surfaces with 5.5 m thick bauxitic mantle subdivided into 1.5 m thick discontinuous duricrust lying on 4.0 m thick continuous duricrust. The continuous surfaces are 4.1 m thick bauxitic duricrust. Mineralogical studies showed that the Foumban bauxites exhibit 78–86% of gibbsite, 7–22% of goethite and less than 7% of kaolinite. Geochemically, Al is the most abundant element with 45.6–58.7 wt.% of Al2O3; followed by Fe with 12.9–20.1 wt.% of Fe2O3 and Si with 1.0–3.7 wt.% of SiO2. Element mobility stated with enrichment factor (EF) allows differentiating three chemical elements: strongly depleted with EF < 1 (Si, Ca, Mg, K, Na, Cu, Mn, Zn); strictly enriched with EF > 1 (Al, Fe, Cr); and with irregular depletion and enrichment behavior with EF ± 1 (Nb, Sr, V, Zr). Based on mass-transport function (M), elements decrease as follows: Sr > Nb > Cr > Al > Zr > V > Zn > Fe > Cu > Si > Ca > K = Na > Mg > Mn. The Foumban encrusted bauxites are classified as laterite and iron-rich high grade orth-bauxites with 45.6–58.7 wt.% of Al2O3 and 1.0– 3.7 wt.% of SiO2, with bauxite reserves estimated to 75.8 million tons. The mapping approach has shown to be suitable for delineating encrusted bauxitic surfaces within loose laterites in tropical regions.The present study aims at mapping some western Cameroon bauxites combining results of digital processing of satellite data (ETM+ of LandSat) with the geological, structural, mineralogical and geochemical characteristics of the Foumban area. Two categories of encrusted bauxitic surfaces have been identified: (i) discontinuous surfaces covering a total area of 11.13 km2, and (ii) continuous surfaces overlapping 2.41 km2. Field observations portray discontinuous surfaces with 5.5 m thick bauxitic mantle subdivided into 1.5 m thick discontinuous duricrust lying on 4.0 m thick continuous duricrust. The continuous surfaces are 4.1 m thick bauxitic duricrust. Mineralogical studies showed that the Foumban bauxites exhibit 78–86% of gibbsite, 7–22% of goethite and less than 7% of kaolinite. Geochemically, Al is the most abundant element with 45.6–58.7 wt.% of Al2O3; followed by Fe with 12.9–20.1 wt.% of Fe2O3 and Si with 1.0–3.7 wt.% of SiO2. Element mobility stated with enrichment factor (EF) allows differentiating three chemical elements: strongly depleted with EF < 1 (Si, Ca, Mg, K, Na, Cu, Mn, Zn); strictly enriched with EF > 1 (Al, Fe, Cr); and with irregular depletion and enrichment behavior with EF ± 1 (Nb, Sr, V, Zr). Based on mass-transport function (M), elements decrease as follows: Sr > Nb > Cr > Al > Zr > V > Zn > Fe > Cu > Si > Ca > K = Na > Mg > Mn. The Foumban encrusted bauxites are classified as laterite and iron-rich high grade orth-bauxites with 45.6–58.7 wt.% of Al2O3 and 1.0– 3.7 wt.% of SiO2, with bauxite reserves estimated to 75.8 million tons. The mapping approach has shown to be suitable for delineating encrusted bauxitic surfaces within loose laterites in tropical regions.
dc.language.isoen
dc.subjectMapping
dc.subjectLandsat
dc.subjectEnvironment
dc.titleMapping bauxite indices using Landsat ETM+ imageries constrained with environmental factors in Foumban area (West Cameroon)
dc.typeJournal Article
dc.description.versionPeer Review
cg.contributor.affiliationUniversité de Dschang
cg.contributor.affiliationInstitut de Recherche Agricole pour le Développement, Cameroon
cg.contributor.affiliationInternational Institute of Tropical Agriculture
cg.contributor.affiliationNational Ortography Institute,Yaoundé
cg.contributor.affiliationUniversité de Yaoundé
cg.coverage.regionAfrica
cg.coverage.regionCentral Africa
cg.coverage.countryCameroon
cg.isijournalISI Journal
cg.authorship.typesCGIAR and developing country institute
cg.iitasubjectMeteorology And Climatology
cg.journalJournal of African Earth Sciences
cg.howpublishedFormally Published
cg.accessibilitystatusLimited Access
local.dspaceid76394
cg.identifier.doihttps://dx.doi.org/10.1016/j.jafrearsci.2015.05.010


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