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Study of the geo-electrical anisotropy in the Cape Fold Belt using magnetotelluric X. Chen 1, 2 , U. Weckmann 1 1. Helmholtz Centre Potsdam – German Research Centre for Geosciences, Potsdam, Germany 2. Institute of Earth and Environmental Sciences, University of Potsdam, Potsdam, Germany xiaoming@gfz-potsdam.de , uweck@gfz-potsdam.de ABSTRACT Within the framework of the German - South African geo-scientific research initiative Inkaba yeAfrica a series of magnetotelluric (MT) field experiments were conducted along the Agulhas-Karoo Transect in South Africa. This transect crosses several continental collision zones between the Cape Fold Belt, the Namaqua Natal Mobile Belt and the Kaapvaal Craton. Along the Cape Fold Belt profile we can identify areas (> 10km) where MT sites exhibit phases over 90 degrees. This phenomenon usually occurs in presence of electrical anisotropy. Due to the dense site spacing we are able to observe this behaviour consistently at several sites. With isotropic 2D inversion we are able to explain most features in the MT data but not the abnormal phase behaviour. In order to explain the abnormal phase behaviour we have to include zones of electrical anisotropy. Currently, we can use 2D anisotropic forward modelling to reproduce the general trend of phases leaving the quadrant. To explain the MT data in more detail, 2D anisotropic inversion would be desirable. In this presentation we focus on a spatially constraint 2D anisotropic inversion. In a first step, we use simple 2D models with embedded zones of electrical anisotropy to study the general influence of anisotropy parameters. In a second step, isotropic 2D inversion results are used as background models in which we include anisotropic zones in order to fit the abnormal phase curves in the data. For these forward modelling studies we implemented the 2D anisotropic code by Pek & Verner (1997) into the modular EM modelling and inversion software (Egbert, 2006; Egbert & Siripunvaraporn, 2008). The modular system provides an ideal environment to implement this inversion scheme. KEYWORDS: Cape Fold Belt, magnetotelluric, anisotropy, modelling, constraint inversion. 14
Exploring the Origin of Breccia Pipes in the Karoo Basin, South Africa Naledi Chere 1 Maarten De Wit 2 , Dave Reid 3 1. Geological Sciences Department & AEON, University of Cape Town, South Africa, chrnal001@uct.ac.za, 2. maarten.dewit@uct.ac.za, 3. dave.reid@uct.ac.za ABSTRACT In the Karoo Basin enigmatic pipes occur in the western sector of the sedimentary basin-here and elsewhere in the Karoo Bain, the pipes are closely associated with the Mid Jurassic (~180Ma) Karoo Large Igneous Province. It has been suggested that these pipes resulted from the interaction of hot igneous intrusions such as dolerite sills and the surrounding sedimentary units. This project aims to test this model. 21 breccia pipes across Loriesfontein and Calvinia in the Northern Province (South Africa) have been investigated. The pipes outcrop in the sediments of the Ecca Group and occur as low lying circular hills (average height of 15 m) ranging from 20m to 80m in diameter. The centre of the hills are characterised by rocks with calcite infill in the vesicles. The contact between the vesiculated rock at the centre and the country rock is sharp in most pipes. The surrounding rocks either shallowly dip (dip angles 5 to 10 degrees) towards or dome away the centre of the breccia pipe. The rocks display variation in the degree of vesiculation (approximately a maximum of 20%) and calcite infilling across the breccia pipes but long axes of the vesicles typically had a preferred orientation. Microscopic studies of the breccia matrix rock reveal a mineral assemblage of predominantly calcite, quartz and plagioclase laths. The increased porosity of the rock due to its vesicular nature makes them optimal groundwater targets in the Karoo Basin. The further aims of the research are to (1) construct detailed geological maps of at least 10 pipes based on field work using the QuantumGIS system, (2) Petrological analyses of breccia and host rock samples for mineralogy studies using conventional optical microscopy and XRD (3) Bulk rock geochemistry of the samples ( XRF, ICPMS). On the basis of this data, a possible model for the pipes will be constructed. KEYWORDS: Vesicular breccia pipes, Karoo Sedimentary Basin, dolerite dykes/sills 15
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Page 5 and 6: 12:00 Boyd, D. Seismic Interpretati
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Page 72 and 73: An Investigation of the Trace Eleme
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Low Enthalpy Geothermal Energy puri
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Mineralogical, geochemical and stru
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Petrophysical evaluation of the Alb
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Towards a magmatic reaction model f
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Denudation rates and geomorphic evo
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Structural mapping and analysis of
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Monitoring the 2-D urban heat islan
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Statistical Downscaling of Climate
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New insights on the role of a mantl
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Palaeoceanographic changes identifi
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The development and evaluation of s
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Records of Late Quaternary environm
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