Your search found 2 records
1 Premasiri, H. M. R.; Wijeyesekera, D. S.; Weerawarnakula, S.; Puswewala, U. G. A. 2006. Formation of hot water springs in Sri Lanka. Engineer, 39(4):7-12.
(Location: IWMI HQ Call no: PER Record No: H043247)
(0.63 MB)
2 Baumle, R.; Himmelsbach, T.; Noell, U. 2019. Hydrogeology and geochemistry of a tectonically controlled, deep-seated and semi-fossil aquifer in the Zambezi Region (Namibia). Hydrogeology Journal, 27(3):885-914. [doi: https://doi.org/10.1007/s10040-018-1896-x]
Groundwater flow ; Aquifers ; Hydrogeology ; Geochemistry ; Tectonics ; Remote sensing ; Geophysics ; Rain ; Temperature ; Palaeoclimatology ; Models / Africa South of Sahara / Namibia / Zambezi River / Lower Kalahari Aquifer
(Location: IWMI HQ Call no: e-copy only Record No: H049358)
https://link.springer.com/content/pdf/10.1007%2Fs10040-018-1896-x.pdf
https://vlibrary.iwmi.org/pdf/H049358.pdf
https://vlibrary.iwmi.org/pdf/H049358.pdf
(16.60 MB) (16.6 MB)
Recent exploration has revealed that deep-seated and large groundwater reservoirs in Africa’s intracontinental basins can be regarded as an additional strategic resource for supply of drinking water. The origin, genesis and recharge of these groundwater reservoirs, however, are still poorly understood. A multidisciplinary approach involving remote sensing, geophysical surveys and hydraulic investigations, as well as hydrochemical and isotope studies, was pursued to gain better insight into the genesis and the potential of a recently discovered lower Kalahari aquifer (LKA) located in the Zambezi Region (Namibia). The study shows that regional tectonic activity associated with the propagation of the Okavango Rift Zone had a tremendous impact on the drainage evolution and hydrogeological setting of the region. Furthermore, there is geomorphological evidence that the LKA—prior to tectonic subsidence and burial—was part of a paleochannel of the upper Zambezi River. Hydraulic continuity could be confirmed by geochemical evolution down the flow path. Cation exchange combined with dissolution of calcite progressively produces alkalinity and sodium and consumes calcium in the north–south direction. Comparison of stable isotope content of the LKA with modern rainfall indicates that the recharge occurred under cooler climate conditions. Analysis of 14C concentrations and 36Cl/Cl ratios show that the age of the groundwater exceeds 100 ka and is hence older than presumed. It is concluded that the assessment of the sedimentology, tectonic structures and geochemistry are key factors for understanding both the paleoclimatic and modern recharge processes of deep-seated aquifer systems.
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