Browsing by Author "Macheyeki, Athanas S."
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Item Morphostructure, paleostress and kinematics of the southern kilombero rift basin, southern Tanzania(Elsevier BV, 2024) Keraka, Godfrey Richard; Macheyeki, Athanas S.; Shaban, MarcoIn recent years, there has been exploration for hydrocarbons in the Kilombero rift basin. However, detailed information regarding the structural pattern and kinematics within the basin, as well as the border fault has not been established. Structures play a crucial role in determining the presence of gas/and oil in a reservoir, making them vital in assessing hydrocarbon resources. Specifically, understanding whether the basin, its border fault (s) and intrabasinal faults are seismically active or not is essential in evaluating the potential for hydrocarbon reserves in a given area. This study therefore, focuses on conducting a morphostructural and paleostress analysis of the southern Kilombero rift to establish important fault parameters, including the current rift kinematics. In the morphostructural analysis, we find that the southern Kilombero rift border fault is a nearly 100 km long segmented structure characterized by an escarpment height of approximately 1300 m. Additionally, analysis of about 40 fault/extensional fracture surfaces indicates that the border fault, which is believed to be from the Early Pliocene period (around 5 ± 1 million years ago) and trending about 042°/222° (NE-SW), is under pure extensional stresses characterized by horizontal minimum principal stress axis (Shmin) of about 060°, implying that faults trending 330°/150° (NW-SE) are the ones associated with this extensional direction. However, a computed stress tensor from focal mechanisms show Shmin = 112° (ESE-WNW) meaning that NNE-SSW trending faults (i.e. 022°/202°) are currently active. Presence of these two pure extensional regime (with minor compression component) imply that the stress regime has either rotated through 52° in a clockwise direction from Shmin = 60° to Shmin = 112° in the Quaternary or that this latter extensional direction computed from seismic data represents a local/temporary tectonic phenomenon caused by changing far-field stresses. The stress tensors derived from our modeling efforts shed light on the regional stress conditions within the southern segment of the East African Rift System (EARS), to which our study area belongs. These revelations collectively suggest a transitional evolution of the geomorphology within the southern Kilombero rift basin, with a shift from a half graben configuration towards a full graben-horst-full graben system. This structural transformation enhances the basin's potential as a viable candidate for hydrocarbon accumulation. Strike-slip faults are also present but are not significant.Item Morphostructure, paleostress and kinematics of the southern kilombero rift basin, southern Tanzania(Elsevier BV, 2024) Keraka, Godfrey R.; Macheyeki, Athanas S.; Shaban, M.In recent years, there has been exploration for hydrocarbons in the Kilombero rift basin. However, detailed information regarding the structural pattern and kinematics within the basin, as well as the border fault has not been established. Structures play a crucial role in determining the presence of gas/and oil in a reservoir, making them vital in assessing hydrocarbon resources. Specifically, understanding whether the basin, its border fault (s) and intrabasinal faults are seismically active or not is essential in evaluating the potential for hydrocarbon re serves in a given area. This study therefore, focuses on conducting a morphostructural and paleostress analysis of the southern Kilombero rift to establish important fault parameters, including the current rift kinematics. In the morphostructural analysis, we find that the southern Kilombero rift border fault is a nearly 100 km long segmented structure characterized by an escarpment height of approximately 1300 m. Additionally, analysis of about 40 fault/extensional fracture surfaces indicates that the border fault, which is believed to be from the Early Pliocene period (around 5 ± 1 million years ago) and trending about 042◦/222◦ (NE-SW), is under pure extensional stresses characterized by horizontal minimum principal stress axis (Shmin) of about 060◦, implying that faults trending 330◦/150◦ (NW-SE) are the ones associated with this extensional direction. However, a computed stress tensor from focal mechanisms show Shmin = 112◦ (ESE-WNW) meaning that NNE-SSW trending faults (i.e. 022◦/202◦) are currently active. Presence of these two pure extensional regime (with minor compression component) imply that the stress regime has either rotated through 52◦ in a clockwise direction from Shmin = 60◦ to Shmin = 112◦ in the Quaternary or that this latter extensional direction computed from seismic data represents a local/temporary tectonic phenomenon caused by changing far-field stresses. The stress tensors derived from our modeling efforts shed light on the regional stress conditions within the southern segment of the East African Rift System (EARS), to which our study area belongs. These revelations collectively suggest a transitional evolution of the geomorphology within the southern Kilombero rift basin, with a shift from a half graben configuration towards a full graben-horst-full graben system. This structural transformation en hances the basin’s potential as a viable candidate for hydrocarbon accumulation. Strike-slip faults are also present but are not significant.Item Present-day fault kinematics and their reactivation likelihood within and south of the north Tanzania divergence (NTD), East African rift system: implication for geo-hazards assessment(Geological Society of India, 2024) Macheyeki, Athanas S.This study investigates the relationship between the North Tanzania Divergence (NTD), the southern part of the NTD and the rift structures in the eastern part of the East African Rift System (EARS). It also assesses the susceptibility of these structures to reactivation under the current stress field. Fault slip data and focal mechanisms from various sources have been used to determine the minimum horizontal stress axes (Shmin) of different faults, including the Eyasi rift border fault south of the NTD. The analysis reveals that faults trending NW-SE to NNW-SSE have a sinistral sense of movement, while those trending NE-SW generally have a dextral sense of movement. The N60°E trending faults that dip easterly are not optimally oriented with the current stress field and have a low to moderate likelihood of reactivation. This includes the NE-SW trending Eyasi rift border fault (part of the NTD) and other structures oriented N60°E south of the NTD, with a computed slip tendency (Ts) of less than 0.5. Faults trending N-S, NNW-SSE, and NNE-SSW, on the other hand, have a high to the highest likelihood of reactivation (Ts > 0.85). The other faults in the study area, which trend NE-SW or NW-SE, have Ts values expressed as 0.5 ≤ Ts < 0.85. These findings have important implications for earthquake risk assessment in the NTD and south of the NTD, as geological constraints need to be taken into account for better management and mitigation. The results could be applied elsewhere in the EARS provided that they are under E-W extensional stress regime.