Warming climate intensifies flash droughts worldwide—study defines and tracks critical measures of drought severity (Image Credit: Phys.org)
Sudden, severe dry spells known as flash droughts are rising in intensity around the world, with a notable exception in mountainous Central Asia, where flash drought extent is shrinking, according to new research published in Geophysical Research Letters. Heat and changes to precipitation patterns caused by a warming climate are driving these trends, the study found.
Flash droughts arrive suddenly, within weeks, hitting communities that are often not prepared and causing lasting impact. They are an emerging concern for water and food security. The new study is the first to apply a systematic, quantitative approach to the global incidence of flash drought, mapping hotspots and regions of rapid increases in recent decades.
“For many parts of the world, we saw flash droughts extending over larger areas, for longer time, with faster onset speed,” said Maheshwari Neelam, a climate scientist at NASA’s Marshall Space Flight Center and the Universities Space Research Association.
The study defined and tracked three critical measures of drought severity: speed of onset, duration and geographic extent. It analyzed 40 years of NASA’s MERRA-2 climate data, from 1980 to 2019, drawn from weather observations, satellite imagery and modeled root-zone soil moisture, with the aim of improving prediction and disaster preparedness.
“For example, in watersheds in South America, onset is getting faster by about 0.12 days per year, so over a decade they are developing a day earlier. Extent is increasing by 1 to 3% per year,” Neelam said. “The metrics can be used by early warning systems to incorporate rates of change in flash drought characteristics in risk assessment and disaster preparedness.”
South America, particularly southern Brazil and the Amazon, is experiencing strong intensification in all three dimensions of flash drought, aligning with deforestation patterns in the region, high temperatures and less rain. Congo, Angola, Zambia, Zimbabwe, South Africa, Lesotho, and Madagascar are also hotspots. High temperatures were found to be more important than declining precipitation in the African watersheds.
Land cover is also important to flash drought vulnerability. Savanna and grasslands are more susceptible to flash droughts than other ecotypes, particularly in humid and semi-humid climates, the study found.
In Central Asian watersheds, centered on high mountains, including the Himalaya Karakoram, Tianshan and Hindu Kush, flash drought extent shrank over the study period, bucking the worldwide trend. Climate-driven changes in precipitation, melting snowpack and a shift from snow to rain in the mountains have kept soils moist. These changes can cause an increase in flash floods, which have been observed in the region, Neelam said.
Neelam emphasized the importance of understanding landscapes’ response to disasters on a watershed scale for assessing water budgets and water management, transcending geopolitical boundaries.
“Natural hazards have no political values,” Neelam said. “This is why we looked at watersheds and not countries.”
More information:
Maheshwari Neelam et al, Global Flash Droughts Characteristics: Onset, Duration, and Extent at Watershed Scales, Geophysical Research Letters (2024). DOI: 10.1029/2024GL109657
Journal information:
Geophysical Research Letters
Provided by
American Geophysical Union
Warming climate intensifies flash droughts worldwide—study defines and tracks critical measures of drought severity (2024, May 21)
retrieved 22 May 2024
from https://phys.org/news/2024-05-climate-droughts-worldwide-tracks-critical.html
part may be reproduced without the written permission. The content is provided for information purposes only.