Miller JA, J. A. and Dunford AJ, A. J. and Swana KA, K. A. and Palcsu, László and Butler, M. (2017) Stable isotope and noble gas constraints on the source and residence time of spring water from the Table Mountain Group Aquifer, Paarl, South Africa and implications for large scale abstraction. JOURNAL OF HYDROLOGY, 551. pp. 100-115. ISSN 0022-1694
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Abstract
Large scale groundwater abstraction is increasingly being used to support large urban centres especially in areas of low rainfall but presents particular challenges in the management and sustainability of the groundwater system. The Table Mountain Group (TMG) Aquifer is one of the largest and most important aquifer systems in South Africa and is currently being considered as an alternative source of potable water for the City of Cape Town, a metropolis of over four million people. The TMG aquifer is a fractured rock aquifer hosted primarily in super mature sandstones, quartzites and quartz arenites. The groundwater naturally emanates from numerous springs throughout the cape region. One set of springs were examined to assess the source and residence time of the spring water. Oxygen and hydrogen isotopes indicate that the spring water has not been subject to evaporation and in combination with Na/Cl ratios implies that recharge to the spring systems is via coastal precipitation. Although rainfall in the Cape is usually modelled on orographic rainfall, δ18O and δ2H values of some rainfall samples are strongly positive indicating a stratiform component as well. Comparing the spring water δ18O and δ2H values with that of local rainfall, indicates that the springs are likely derived from continuous bulk recharge over the immediate hinterland to the springs and not through large and/or heavy downpours. Noble gas concentrations, combined with tritium and radiocarbon activities indicate that the residence time of the TMG groundwater in this area is decadal in age with a probable maximum upper limit of ∼40 years. This residence time is probably a reflection of the slow flow rate through the fractured rock aquifer and hence indicates that the interconnectedness of the fractures is the most important factor controlling groundwater flow. The short residence time of the groundwater suggest that recharge to the springs and the Table Mountain Group Aquifer as a whole is vulnerable to climate change and reductions in regional precipitation. Any plans for large scale abstraction to supplement the City of Cape Town water supply would need to factor this into models of maximum sustainable yield. © 2017 Elsevier B.V.
Item Type: | Article |
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Uncontrolled Keywords: | Recharging (underground waters); Table mountain groups; residence time; Oxygen and hydrogen isotopes; Maximum sustainable yields; groundwater abstraction; Ground water recharge; Fractured rock aquifers; water supply; Springs (components); Rain; Potable water; Landforms; ISOTOPES; Inert gases; Groundwater resources; groundwater flow; GROUNDWATER; Climate change; Aquifers; Abstracting; Table Mountain Group Aquifer; Stable isotopes; SPRINGS; RESIDENCE TIMES; noble gases; Groundwater recharge |
Subjects: | Q Science / természettudomány > QE Geology / földtudományok > QE08 Hydrosphere. Hydrology / hidroszféra, hidrológia |
SWORD Depositor: | MTMT SWORD |
Depositing User: | MTMT SWORD |
Date Deposited: | 12 Feb 2018 14:27 |
Last Modified: | 12 Feb 2018 14:27 |
URI: | http://real.mtak.hu/id/eprint/74336 |
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