River system retentiveness must be enhanced to increase multidimensional environmental sustainability and thus ameliorate the effects of climate change and the occurrence of extreme hydrological events. The aim of the article is to demonstrate how ecohydrological Nature-Based Solutions can be combined with conventional infrastructure to improve WBSRCE benefits (Water, Biodiversity, ecosystem Services, Resilience, Culture, Education) by taking a holistic approach to multifunctional reservoir design. The paper proposes a new form of lateral reservoir, which is built without disturbing the meandering river and is supplied with good quality water through a monitoring and regulatory system; its design is based on thorough analysis of hydrological pulses and suspended matter and nutrients fluxes. The regulatory system also includes an innovative Sequential Sedimentation and Biofiltration System. Lateral reservoirs increase water retentiveness in the river valley by lifting ground water level and restoring surrounding wetlands, thus enhancing biodiversity, ecosystem services for society and the resilience of the river system to climate change. An integrative understanding of the interplay between hydrology and biocenosis can be used to enhance river system sustainability potential (WBSR) and harmonise societal needs with biosphere sustainability through culture and education (CE).
Keywords: Climate change; Drought; Ecohydrology; Eutrophication; Lateral reservoir construction; Nature-Based Solutions; WBRSCE; Water retentiveness.
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