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1 Faye, S. C.; Diongue, M. L.; Pouye, A.; Gaye, C. B.; Travi, Y.; Wohnlich, S.; Faye, S.; Taylor, R. G. 2019. Tracing natural groundwater recharge to the Thiaroye Aquifer of Dakar, Senegal. Hydrogeology Journal, 27(3):1067-1080. (Special issue: Groundwater in Sub-Saharan Africa) [doi: https://doi.org/10.1007/s10040-018-01923-8]
Groundwater recharge ; Aquifers ; Semiarid zones ; Urban areas ; Groundwater flow ; Groundwater table ; Monsoon climate ; Rain ; Chemical composition ; Isotopes / Senegal / Dakar / Thiaroye aquifer
(Location: IWMI HQ Call no: e-copy only Record No: H049362)
https://link.springer.com/content/pdf/10.1007%2Fs10040-018-01923-8.pdf
https://vlibrary.iwmi.org/pdf/H049362.pdf
https://vlibrary.iwmi.org/pdf/H049362.pdf
(5.43 MB) (5.43 MB)
Urban groundwater in Sub-Saharan Africa provides vital freshwater to rapidly growing cities. In the Thiaroye aquifer of Dakar (Senegal), groundwater within Quaternary unconsolidated sands provided nearly half of the city’s water supply into the 1980s. Rising nitrate concentrations traced to faecal contamination sharply curtailed groundwater withdrawals, which now contribute just 5% to Dakar’s water supply. To understand the attenuation capacity of this urban aquifer under a monsoonal semi-arid climate, stable-isotope ratios of O and H and radioactive tritium (3H), compiled over several studies, are used together with piezometric data to trace the origin of groundwater recharge and groundwater flowpaths. Shallow groundwaters derive predominantly from modern rainfall (tritium >2 TU in 85% of sampled wells). d18O and d2H values in groundwater vary by >4 and 20‰, respectively, reflecting substantial variability in evaporative enrichment prior to recharge. These signatures in groundwater regress to a value on the local meteoric water line that is depleted in heavy isotopes relative to the weighted-mean average composition of local rainfall, a bias that suggests recharge derives preferentially from isotopically depleted rainfall observed during the latter part of the monsoon (September). The distribution of tritium in groundwater is consistent with groundwater flowpaths to seasonal lakes and wetlands, defined by piezometric records. Piezometric data further confirm the diffuse nature and seasonality of rain-fed recharge. The conceptual understanding of groundwater recharge and flow provides a context to evaluate attenuation of anthropogenic recharge that is effectively diffuse and constant from the vast network of sanitation facilities that drain to this aquifer.
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