4.7 Article

Hydrological Intensification Will Increase the Complexity of Water Resource Management

Journal

EARTHS FUTURE
Volume 10, Issue 3, Pages -

Publisher

AMER GEOPHYSICAL UNION
DOI: 10.1029/2021EF002487

Keywords

climate change; water resources; hydrology; precipitation; evaporative demand

Funding

  1. Lilly Endowment, Inc.
  2. National Science Foundation [CNS-0521433]
  3. USDA National Institute of Food and Agriculture [2021-69012-35916]
  4. National Sciences Foundation [1653452]
  5. Div Of Chem, Bioeng, Env, & Transp Sys
  6. Directorate For Engineering [1653452] Funding Source: National Science Foundation

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Global warming intensifies the hydrological cycle, resulting in more extreme precipitation events and longer dry spells. Previous studies have focused on precipitation without considering changes in evaporative demand and plant responses. Using state-of-the-art climate models, we examine projected changes in hydrological intensification and its impact on water resources management. Our findings show that surplus events will become larger and more frequent, with the greatest changes expected in the northern latitudes. These extreme events will stress existing water management infrastructure in major river basins, particularly those with large reservoir capacity.
Global warming intensifies the hydrological cycle by altering the rate of water fluxes to and from the terrestrial surface, resulting in an increase in extreme precipitation events and longer dry spells. Prior hydrological intensification work has largely focused on precipitation without joint consideration of evaporative demand changes and how plants respond to these changes. Informed by state-of-the-art climate models, we examine projected changes in hydrological intensification and its role in complicating water resources management using a framework that accounts for precipitation surplus and evaporative demand. Using a metric that combines the difference between daily precipitation and daily evaporative demand (surplus events) and consecutive days when evaporative demand exceeds precipitation (deficit time), we show that, globally, surplus events will become larger (+11.5% and +18.5% for moderate and high emission scenarios, respectively) and the duration between them longer (+5.1%; +9.6%) by the end of the century, with the largest changes in the northern latitudes. The intra-annual occurrence of these extremes will stress existing water management infrastructure in major river basins, where over one third of years during 2070-2100 under a moderate emissions scenario will be hydrologically intense (large intra-annual increases in surplus intensity and deficit time), tripling that of the historical baseline. Larger increases in hydrologically intense years are found in basins with large reservoir capacity (e.g., Amazon, Congo, and Danube River Basins), which have significant populations, irrigate considerable farmland, and support threatened and endangered aquatic species. Incorporating flexibility into water resource infrastructure and management will be paramount with continued hydrological intensification.

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