Abstract
Rainwater is conventionally perceived as an alternative drinking water source, mostly needed to meet water demand under particular circumstances, including under semi-arid conditions and on small islands. More recently, rainwater has been identified as a potential source of clean drinking water in cases where groundwater sources contain high concentrations of toxic geogenic contaminants. Specifically, this approach motivated the introduction of the Kilimanjaro Concept (KC) to supply fluoride-free water to the population of the East African Rift Valley (EARV). Clean harvested rainwater can either be used directly as a source of drinking water or blended with polluted natural water to meet drinking water guidelines. Current efforts towards the implementation of the KC in the EARV are demonstrating that harvesting rainwater is a potential universal solution to cover ever-increasing water demands while limiting adverse environmental impacts such as groundwater depletion and flooding. Indeed, all surface and subsurface water resources are replenished by precipitation (dew, hail, rain, and snow), with rainfall being the main source and major component of the hydrological cycle. Thus, rainwater harvesting systems entailing carefully harvesting, storing, and transporting rainwater are suitable solutions for water supply as long as rain falls on earth. Besides its direct use, rainwater can be infiltrating into the subsurface when and where it falls, thereby increasing aquifer recharge while minimizing soil erosion and limiting floods. The present paper presents an extension of the original KC by incorporating Chinese experience to demonstrate the universal applicability of the KC for water management, including the provision of clean water for decentralized communities.
Highlights
Climate change, population growth, and rapid industrialization are regarded as the three main global drivers increasing stresses on safe drinking water supply worldwide [1,2,3,4,5,6,7,8,9,10,11,12,13]
In the late 1880s, Parkes [16] summarized the value of rainwater as a source of supply as follows: (i) its general good quality and great aeration make it both healthy and pleasant, (ii) the greatest benefits occur when rainwater is used for drinking water supply instead of spring or well water, which is often largely impregnated with salts, and (iii) in cases of cholera, rainwater is less likely to become contaminated with sewage than wells or springs
This current communication extends the Kilimanjaro Concept initially developed to overcome the human health risks associated with high concentrations of toxic geogenic contaminants in groundwater
Summary
Population growth, and rapid industrialization are regarded as the three main global drivers increasing stresses on safe drinking water supply worldwide [1,2,3,4,5,6,7,8,9,10,11,12,13]. There is a 170-year-expertise on drinking water provision including; treatment, storage, conservation and transportation over long distances In these efforts, rainwater (RW) has been used only in some specific situations as it was considered that storing it for dry periods would be challenging [16]. Due to its flexibility and adaptability, scope exists to extend it to other countries in Africa and elsewhere with similar problems In this regard, the KC can be adapted to regions in Asia and South America, where high concentrations of geogenic contaminants (e.g., As, F, U) in drinking water pose severe human health risks [21]. A key advantage of this approach is a limited energy requirement for water treatment associated with conventional technologies
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