Hydrocarbon potential of the Prince Albert Formation, Ecca Group in the main Karoo Basin, South Africa.

Mosavel, Haajierah

January 2020

Philosophiae Doctor - PhD / This thesis focusses on the hydrocarbon potential of the Prince Albert Formation in terms of its shale gas potential. Unconventional gas production from hydrocarbon-rich shale formations, known as “shale gas”, is one of the most rapidly expanding trends in onshore oil and gas exploration and exploitation today. In South Africa, the southern portion of the main Karoo Basin is potentially favourable for shale gas accumulation and may become a game changer in the energy production regime of the country. The Prince Albert Formation was selected for research, since previous studies in South Africa have focused on shale from the Whitehill Formation, which together with the underlying Prince Albert Formation, occur within the lower Ecca Group in the main Karoo Basin. The petrophysical properties and shale gas potential of the Prince Albert Formation was determined using the parameters of mercury porosimetry, total organic carbon (TOC), vitrinite reflectance, Rock-Eval and residual gas measurements. The lithostratigraphy, rock classification, and depositional environment of the Prince Albert Formation, together with the adjacent parts of the overlying Whitehill Formation and underlying Dwyka Group within the southern part of the main Karoo Basin were addressed. Rock types were characterised using X-ray fluorescence (XRF), X-Ray diffraction (XRD) and statistical analysis. Geochemical proxies and stable isotopes (δ18O, δ13C and δ15N) were used to identify the depositional environment. Additionally, the Dwyka Group, Prince Albert and Whitehill formations were correlated with equivalent Southern Gondwanaland units to understand basin development. The results of the shale gas study of the Prince Albert Formation showed porosities ranging between 0.08 and 5.6%, permeabilities between 0 and 2.79 micro-Darcy, TOC between 0.2 and 4.9 weight % and vitrinite reflectance values between 3.8 to 4.9%. Rock-Eval analysis indicated that the kerogen in the shale was Type III and IV and hydrogen indices were less than 65 mg/g. Free or absorbed gas was not detected in the recently drilled boreholes KZF-01 and KWV-01 used in this study. It is probable that the absence of gas is a result of overmaturity due to tectonic duplication in KZF-01 and thermal degassing associated with dolerite intrusions in KWV-01. Although the porosity and TOC values of the Prince Albert Formation shales across the southern part of the main Karoo Basin are comparable with, but at the lower limits of, those of the gas-producing Marcellus shale in the United States (porosities between 1 and 6% and TOC between 1 and 10 weight %), the high vitrinite reflectance values indicate that the shales are overmature with questionable potential for generating dry gas. A comprehensive rock classification were compiled for the Prince Albert Formation, which consists of shale and minor ferruginous shale ranging between thicknesses of 30 and 168 m based on field work and core descriptions. Mineralogical, geochemical and statistical data, classified collected samples as Fe-shale, phosphatic shale, manganiferous shales, shale, wacke, Fe-sand and litharenite. In unconventional resources, understanding the depositional environment is important in delineating the depositional process and bottom water conditions. The Prince Albert Formation was interpreted as marine forming under dysoxic to euxinic conditions. δ 13C values range between -17.5 and -23.1 ‰ and δ 15N between 8.5 and 11.1 ‰ reflecting marine conditions. Sediments of the Prince Albert Formation were interpreted as middle to outer continental shelf deposits based on various lithologies identified and XRF data (geochemical proxies). Compiled literature of the karoo- type basins in Southern Gondwanaland provides a correlation of the Dwyka Group, Prince Albert and Whitehill formations in South Africa. Based on stratigraphy and radiometric dating, the Dwyka Group, Prince Albert and Whitehill formations have been correlated with lithostratigraphic units in the Falkland Islands, Namibia (Huab, Karasburg and Aranos basins), the Ellsworth Basin of Antarctica and the Sauce Grande and Parana basins of South America. This correlation suggest that the main Karoo foreland system was subjected to very similar tectonic influences present in the other karoo-type basins of Southern Gondwanaland. In conclusion, results from this research indicate that viable conditions for shale gas might exist within the “sweet spot” areas constrained by formation thickness being > 30 m, relative dolerite intrusion of < 20%, relative total organic carbon content > 4 weight %, and maturity of < 3.5%. It is essential that new exploration boreholes be drilled within the “sweet spot” areas to test whether the lower Ecca Group (Prince Albert and Whitehill formations) has the potential to generate viable shale gas.

Prince Albert Formation

Main Karoo Basin

Whitehill Formation

Dwyka Group

Shale

The vegetation ecology of the Witteberg and Dwyka Groups south of Worcester, Western Cape Province, South Africa

Le Roux, Anso

01 1900

The vegetation supported by the Witteberg and Dwyka Groups south of Worcester is a diverse mosaic of fynbos-, renosterveld- and succulent karoo vegetation units sustained by a winter-rainfall pattern. Elytropappus rhinocerotis (renosterbos) dominated plant communities are found on finer grained soils derived from the various mudrock-dominated formations of the Witteberg Group, a Passerina truncata (gonnabos) dominated shrubland with large Protea shrubs and / or small Protea trees where the substrate is largely influenced by the sandstone-dominated formations of the Witteberg Group, a grass dominated Capeochloa arundinacea (Olifantgras) shrubland where both mudrock-dominated and sandstone-dominated formations influence the substrate as a result of folding, a karoo Hirpicium integrifolium (Haarbossie) dominated shrubland where succulents are in abundance on the Dwyka tillite, and a distinct Thamnochortus bachmannii restio-dominated sandveld in areas where deep aeolian sand had accumulated. The differences in vegetation communities are mainly based on geology with consequent soil characters and degree of rockiness, as well as topography, moisture availability and the water holding capacity of the soil. Although slope, aspect and elevation can sometimes be associated with specific plant communities, geology, soil pH and rock cover are the principal elements responsible for shaping the vegetation mosaic. Rather than a broad ecotone, the vegetation of the study area is understood as a complex mosaic mountain vegetation entity. / Environmental Sciences / Ph. D. (Environmental Sciences)

Witteberg Group

Dwyka Group

Geology

Soil characters

Rockiness

Topography

Soil water holding capacity

Winter-rainfall

Mmosaic mountain vegetation