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dc.contributor.authorDo Cabo, Vistorina Nandigolo
dc.date.accessioned2014-06-17T11:41:11Z
dc.date.issued2013-04-29
dc.description.abstractThis study considered the geology, mineralogy, geochemistry, formation and evolution of the heavy rare earth element (HREE) mineralised Lofdal alkaline carbonatite complex (LACC), which is located on the Bergville and Lofdal farms northwest of Khorixas, in the Kunene Region of the Republic of Namibia. . Field methods used included mapping, ground and hyperspectral airborne geophysics, and sampling. Analytical techniques used were optical petrography and CL, XRF, ICP-AES, backscattered and secondary electron imaging, electron microprobe, LA-ICP-MS, leaching, as well as carbon and oxygen stable isotope determination. The LACC comprises a swarm of dykes, mainly calcite carbonatite but also dolomite and ankerite carbonatite dykes (classified into five types) and two newly discovered plugs of calcite carbonatite (‘Main’ and ‘Emanya’), with associated dykes and plugs of phonolites, syenites and rare mafic rocks. These all intrude into the Huab Metamorphic Complex basement rocks within a NE-SW shear zone over 30 km long. The main HREE host mineral is xenotime-(Y). It occurs in highly oxidised iron-rich calcite carbonatite dykes mantling and replacing zircon, associated with hematite, thorite and apatite, or associated with monazite-(Ce), synchysite-(Ce), and parisite-(Ce), replacing the fluorocarbonates; it also forms aggregates in ankerite carbonatite. Although xenotime-(Y) occurs throughout the paragenetic sequence, there is much evidence for hydrothermal fluid activity at Lofdal, altering the dykes, and taking xenotime-(Y) into brecciated carbonate veins in albitised country rock (fenite). Radiogenic (Sr, Nd-Sm, U-Pb) and C and O stable isotope studies confirm that the carbonatite, derived from an enriched mantle, is the source of the REE. Mineralisation was contemporaneous with carbonatite emplacement at 765 ±16 Ma. Magmatic fluids >300°C were diluted with cool meteoric fluids. Abundant fluorite and carbonate indicate roles for F- and CO32- in addition to Cl- in REE transport. These ligands form the most stable complexes with HREE and since xenotime is soluble in concentrated alkali halide solutions, they could have preferentially transported and then deposited xenotime. Many of the features of Lofdal are common to other REE-rich carbonatite complexes but the xenotime-(Y) abundance is so far unique. The high amount of fluid activity in shear zones around the dyke swarm and probably a higher proportion of HREE in the original magmas seem to be the main differentiating features.en_GB
dc.description.sponsorshipMinistry of Mines and Energy, Energy Africa PTY Ltd, Africa American Institute and Ministry of Education of Namibiaen_GB
dc.identifier.grantnumberN/Aen_GB
dc.identifier.urihttp://hdl.handle.net/10871/15034
dc.language.isoenen_GB
dc.publisherUniversity of Exeteren_GB
dc.relation.sourceResearchen_GB
dc.rights.embargoreasonI wish to publish a paper related to this thesisen_GB
dc.rightsN/Aen_GB
dc.subjectHeavy Rare Earth Elementsen_GB
dc.subjectxenotimeen_GB
dc.subjectcarbonatiteen_GB
dc.subjectLofdal namibiaen_GB
dc.titleGeological, Mineralogical and Geochemical Characterisation of the Heavy Rare Earth-rich Carbonatites at Lofdal, Namibiaen_GB
dc.typeThesis or dissertationen_GB
dc.contributor.advisorWall, Frances
dc.contributor.advisorWilliamson, Ben
dc.publisher.departmentEarth Sciencesen_GB
dc.type.degreetitlePhD in Earth Resourcesen_GB
dc.type.qualificationlevelDoctoralen_GB
dc.type.qualificationnamePhDen_GB


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