Your search found 2 records
1 Jakubinsky, J.; Prokopova, M.; Raska, P.; Salvati, L.; Bezak, N.; Cudlin, O.; Cudlin, P.; Purkyt, J.; Vezza, P.; Camporeale, C.; Danek, J.; Pastor, M.; Lepeska, T. 2021. Managing floodplains using nature-based solutions to support multiple ecosystem functions and services. WIREs Water, 8(5):e1545. [doi: https://doi.org/10.1002/wat2.1545]
Floodplains ; Ecosystem services ; Natural environment ; Rivers ; Vegetation ; Habitats ; Landscape ; Land use ; Sediment ; Case studies / Europe / Czechia / Slovakia / Italy
(Location: IWMI HQ Call no: e-copy only Record No: H050581)
https://wires.onlinelibrary.wiley.com/doi/epdf/10.1002/wat2.1545
https://vlibrary.iwmi.org/pdf/H050581.pdf
https://vlibrary.iwmi.org/pdf/H050581.pdf
(3.50 MB) (3.50 MB)
Floodplains include unique environments shaped over a long time horizon along rivers and smaller streams and formed by alluvial sediments. As floodplains are flat, often with highly fertile and well-accessible land, they have become the intrinsic focus of human society—while providing a variety of goods and ecosystem services. Intensive land use of floodplains is degrading their natural values and significantly reducing their ecosystem functions and services. A significant part of these key services is related with the ability of floodplains to retain water and nutrients, which can be understood as a flood control and a water-retention function. Although these ecosystems serve a number of other basic functions, the importance of floodplains as a place for water retention during extreme discharges caused by intense rainfall or snowmelt and the supply of water in times of drought are essential under conditions of global change. In order to increase the ability of floodplains to perform these functions, it is increasingly required to preserve the connectivity of rivers with surrounding floodplains and adapt human activities to maintain and restore river ecosystems. This article reviews the recent understanding of floodplain delineation, the most common causes of disturbance, the ecosystem functions being performed, discussing in turn the measures being considered to mitigate the frequency and magnitude of hydrologic extremes resulting from ongoing environmental changes.
2 Arheimer, B.; Cudennec, C.; Castellarin, A.; Grimaldi, S.; Heal, K. V.; Lupton, C.; Sarkar, A.; Tian, F.; Onema, J.-M. K.; Archfield, S.; Blöschl, G.; Chaffe, P. L. B.; Croke, B. F. W.; Dembélé, Moctar; Leong, C.; Mijic, A.; Mosquera, G. M.; Nlend, B.; Olusola, A. O.; Polo, M. J.; Sandells, M.; Sheffield, J.; van Hateren, T. C.; Shafiei, M.; Adla, S.; Agarwal, A.; Aguilar, C.; Andersson, J. C. M.; Andraos, C.; Andreu, A.; Avanzi, F.; Bart, R. R.; Bartosova, A.; Batelaan, O.; Bennett, J. C.; Bertola, M.; Bezak, N.; Boekee, J.; Bogaard, T.; Booij, M. J.; Brigode, P.; Buytaert, W.; Bziava, K.; Castelli, G.; Castro, C. V.; Ceperley, N. C.; Chidepudi, S. K. R.; Chiew, F. H. S.; Chun, K. P.; Dagnew, A. G.; Dekongmen, B. W.; del Jesus, M.; Dezetter, A.; do Nascimento Batista, J. A.; Doble, R. C.; Dogulu, N.; Eekhout, J. P. C.; Elçi, A.; Elenius, M.; Finger, D. C.; Fiori, A.; Fischer, S.; Förster, K.; Ganora, D.; Ellouze, E. G.; Ghoreishi, M.; Harvey, N.; Hrachowitz, M.; Jampani, Mahesh; Jaramillo, F.; Jongen, H. J.; Kareem, K. Y.; Khan, U. T.; Khatami, S.; Kingston, D. G.; Koren, G.; Krause, S.; Kreibich, H.; Lerat, J.; Liu, J.; de Brito, M. M.; Mahé, G.; Makurira, H.; Mazzoglio, P.; Merheb, M.; Mishra, A.; Mohammad, H.; Montanari, A.; Mujere, N.; Nabavi, E.; Nkwasa, A.; Alegria, M. E. O.; Orieschnig, C.; Ovcharuk, V.; Palmate, S. S.; Pande, S.; Pandey, S.; Papacharalampous, G.; Pechlivanidis, I.; Penny, G.; Pimentel, R.; Post, D. A.; Prieto, C.; Razavi, S.; Salazar-Galán, S.; Namboothiri, A. S.; Santos, P. P.; Savenije, H.; Shanono, N. J.; Sharma, A.; Sivapalan, M.; Smagulov, Z.; Szolgay, J.; Teng, J.; Teuling, A. J.; Teutschbein, C.; Tyralis, H.; van Griensven, A.; van Schalkwyk, A. J.; van Tiel, M.; Viglione, A.; Volpi, E.; Wagener, T.; Wang-Erlandsson, L.; Wens, M.; Xia, J. 2024. The IAHS science for solutions decade, with Hydrology Engaging Local People IN a Global world (HELPING). Hydrological Sciences Journal, 50p. (Online first) [doi: https://doi.org/10.1080/02626667.2024.2355202]
Hydrology ; Water scarcity ; Transdisciplinary research ; Local knowledge ; Water security ; Prediction ; Anthropocene ; Stakeholders ; Sustainable Development Goals
(Location: IWMI HQ Call no: e-copy only Record No: H052865)
https://www.tandfonline.com/doi/epdf/10.1080/02626667.2024.2355202?needAccess=true
https://vlibrary.iwmi.org/pdf/H052865.pdf
https://vlibrary.iwmi.org/pdf/H052865.pdf
(4.65 MB) (4.65 MB)
The new scientific decade (2023-2032) of the International Association of Hydrological Sciences (IAHS) aims at searching for sustainable solutions to undesired water conditions - may it be too little, too much or too polluted. Many of the current issues originate from global change, while solutions to problems must embrace local understanding and context. The decade will explore the current water crises by searching for actionable knowledge within three themes: global and local interactions, sustainable solutions and innovative cross-cutting methods. We capitalise on previous IAHS Scientific Decades shaping a trilogy; from Hydrological Predictions (PUB) to Change and Interdisciplinarity (Panta Rhei) to Solutions (HELPING). The vision is to solve fundamental water-related environmental and societal problems by engaging with other disciplines and local stakeholders. The decade endorses mutual learning and co-creation to progress towards UN sustainable development goals. Hence, HELPING is a vehicle for putting science in action, driven by scientists working on local hydrology in coordination with local, regional, and global processes.
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