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- Water resources management should be assessed under climate change conditions, as historic data cannot replicate future climatic conditions. - Climate change impacts on water resources are bound to affect all water uses, i.e., irrigated agriculture, domestic and industrial water supply, hydropower generation, and environmental flow (of streams and rivers) and water level (of lakes). - Bottom-up approaches, i.e., the forcing of hydrologic simulation models with climate change models’ outputs, are the most common engineering practices and considered as climate-resilient water management approaches. - Hydrologic simulations forced by climate change scenarios derived from regional climate models (RCMs) can provide accurate assessments of the future water regime at basin scales. - Irrigated agriculture requires special attention as it is the principal water consumer and alterations of both precipitation and temperature patterns will directly affect agriculture yields and incomes. - Integrated water resources management (IWRM) requires multidisciplinary and interdisciplinary approaches, with climate change to be an emerging cornerstone in the IWRM concept.
Research & information: general --- Precipitation --- Tropical Rainfall Measurement Mission (TRMM) --- Multi-Satellite Precipitation Analysis (TMPA) --- Upper Indus Basin (UIB) --- Himalaya --- streamflow --- extreme rainfall --- watershed --- dynamics of saline lakes --- extremely changing points --- extreme weather --- temporal trend --- climate change --- salinization --- water resources management --- drinking water --- debris --- water balance --- climatic change --- dam capacity --- simulation of sediment transport --- Athabasca River --- climate projection --- hydrologic modelling --- peak-flow --- return period --- stationary analysis --- non-stationary analysis --- global --- temperature --- precipitation --- Net Irrigation Water Requirement --- maize --- hydrologic modeling --- reanalysis gridded datasets --- ERA-Interim --- Balkan Peninsula
Choose an application
- Water resources management should be assessed under climate change conditions, as historic data cannot replicate future climatic conditions. - Climate change impacts on water resources are bound to affect all water uses, i.e., irrigated agriculture, domestic and industrial water supply, hydropower generation, and environmental flow (of streams and rivers) and water level (of lakes). - Bottom-up approaches, i.e., the forcing of hydrologic simulation models with climate change models’ outputs, are the most common engineering practices and considered as climate-resilient water management approaches. - Hydrologic simulations forced by climate change scenarios derived from regional climate models (RCMs) can provide accurate assessments of the future water regime at basin scales. - Irrigated agriculture requires special attention as it is the principal water consumer and alterations of both precipitation and temperature patterns will directly affect agriculture yields and incomes. - Integrated water resources management (IWRM) requires multidisciplinary and interdisciplinary approaches, with climate change to be an emerging cornerstone in the IWRM concept.
Precipitation --- Tropical Rainfall Measurement Mission (TRMM) --- Multi-Satellite Precipitation Analysis (TMPA) --- Upper Indus Basin (UIB) --- Himalaya --- streamflow --- extreme rainfall --- watershed --- dynamics of saline lakes --- extremely changing points --- extreme weather --- temporal trend --- climate change --- salinization --- water resources management --- drinking water --- debris --- water balance --- climatic change --- dam capacity --- simulation of sediment transport --- Athabasca River --- climate projection --- hydrologic modelling --- peak-flow --- return period --- stationary analysis --- non-stationary analysis --- global --- temperature --- precipitation --- Net Irrigation Water Requirement --- maize --- hydrologic modeling --- reanalysis gridded datasets --- ERA-Interim --- Balkan Peninsula
Choose an application
- Water resources management should be assessed under climate change conditions, as historic data cannot replicate future climatic conditions. - Climate change impacts on water resources are bound to affect all water uses, i.e., irrigated agriculture, domestic and industrial water supply, hydropower generation, and environmental flow (of streams and rivers) and water level (of lakes). - Bottom-up approaches, i.e., the forcing of hydrologic simulation models with climate change models’ outputs, are the most common engineering practices and considered as climate-resilient water management approaches. - Hydrologic simulations forced by climate change scenarios derived from regional climate models (RCMs) can provide accurate assessments of the future water regime at basin scales. - Irrigated agriculture requires special attention as it is the principal water consumer and alterations of both precipitation and temperature patterns will directly affect agriculture yields and incomes. - Integrated water resources management (IWRM) requires multidisciplinary and interdisciplinary approaches, with climate change to be an emerging cornerstone in the IWRM concept.
Research & information: general --- Precipitation --- Tropical Rainfall Measurement Mission (TRMM) --- Multi-Satellite Precipitation Analysis (TMPA) --- Upper Indus Basin (UIB) --- Himalaya --- streamflow --- extreme rainfall --- watershed --- dynamics of saline lakes --- extremely changing points --- extreme weather --- temporal trend --- climate change --- salinization --- water resources management --- drinking water --- debris --- water balance --- climatic change --- dam capacity --- simulation of sediment transport --- Athabasca River --- climate projection --- hydrologic modelling --- peak-flow --- return period --- stationary analysis --- non-stationary analysis --- global --- temperature --- precipitation --- Net Irrigation Water Requirement --- maize --- hydrologic modeling --- reanalysis gridded datasets --- ERA-Interim --- Balkan Peninsula --- Precipitation --- Tropical Rainfall Measurement Mission (TRMM) --- Multi-Satellite Precipitation Analysis (TMPA) --- Upper Indus Basin (UIB) --- Himalaya --- streamflow --- extreme rainfall --- watershed --- dynamics of saline lakes --- extremely changing points --- extreme weather --- temporal trend --- climate change --- salinization --- water resources management --- drinking water --- debris --- water balance --- climatic change --- dam capacity --- simulation of sediment transport --- Athabasca River --- climate projection --- hydrologic modelling --- peak-flow --- return period --- stationary analysis --- non-stationary analysis --- global --- temperature --- precipitation --- Net Irrigation Water Requirement --- maize --- hydrologic modeling --- reanalysis gridded datasets --- ERA-Interim --- Balkan Peninsula
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