Abstract
Developing countries such as Malawi require improved access to isotope tracer tools to better characterize and manage water resources threatened by land development, deforestation and climate change. This is the first published study to use an isotope facility developed in Malawi for this purpose, instead of relying upon sample analyses from abroad. Results from this new facility are used to evaluate an important Lake Malawi catchment in the Rift Valley. This work successfully established a stable-isotope baseline, hydrochemical signatures, and system conceptualization against which future policy change and management strategies may be measured. Precipitation isotopic composition was consistent with the Global Meteoric Water Line, but varied, confirming different precipitation systems nationally. Groundwater largely followed a Local Meteoric Water Line, with limited isotopic variation indicating predominant areal groundwater recharge, but with dry-season evaporative enrichment of groundwater near Lake Malawi. Surface-water isotopes widely varied with local precipitation, suggesting the latter accounted for wet-season river flows, but upstream dambo (complex wetlands occupying a shallow, seasonal waterlogged depression) helped sustain dry-season flows. Isotope capacity reinforced water-resource conceptualization and provenance in a hydrologically complex, but not atypical, Rift Valley system, exhibiting a noted complexity of groundwater–surface-water interactions. The latter, critical to integrated water resource management, requires more focused study, to which an expanded array of isotopes will contribute to tracking Sustainable Development Goal 6 targets. This study and future catchment studies should help underpin Malawian water-resource policy implementation on several identified fronts.
Highlights
Water-isotope tracing is a powerful tool for conceptualizing hydrological–hydrogeological systems [1,2,3], including the characterization of hydrological conditions, flow-system evolution, groundwater–surface-water exchange, groundwater recharge and water-source provenance [4,5,6,7]
This study focused on a catchment of the Lake Malawi Basin with contrasting geographies arising from a location at the southern extremity of the East African Rift System
Towards the mid to late dry season there is little, if any, precipitation, with river flows becoming low and tending to a baseflow index (BFI) of unity—flows becoming totally dependent on groundwater baseflow
Summary
Water-isotope tracing is a powerful tool for conceptualizing hydrological–hydrogeological systems [1,2,3], including the characterization of hydrological conditions, flow-system evolution, groundwater–surface-water exchange, groundwater recharge and water-source provenance [4,5,6,7]. Isotopes increasingly underpin integrated water resources management (IWRM) [12,13,14]. Their potential to help strategically address Millennium, and Sustainable Development, Goals (M/SDGs) in the developing world, remains not fully realized. There has still been significant isotopic characterization of African water resources [16], much of those isotope data have been secured through sample export and analysis and interpretation abroad [17,18] This is especially true for developing countries where data can be very sparse [16] and in-house isotope capacity (both analysis and interpretative) fails to develop. African rural resource development has focused almost exclusively on groundwater, typically hand-pumped boreholes for communities [19,20], with little perceived need for isotopes, understanding of the sustainability of the water resource at large, and system linkages
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
