This story was adapted with permission from a NASA press release by Katy Cawdrey and Michael Carlowicz.
Scientists have predicted that droughts and floods will become more frequent and severe as our planet warms and climate changes, but detecting this on regional and continental scales has proven difficult. Now a new UMD and NASA study confirms that major droughts and pluvials – periods of excessive precipitation and water storage on land – have indeed been occurring more often.
In the study published March 13, 2023, in the journal Nature Water, two UMD & NASA scientists examined 20 years of data from the NASA/German GRACE and GRACE-FO satellites to identify extreme wet and dry events. Floods and droughts account for more than 20% of the economic losses caused by extreme weather events in the U.S. each year. The economic impacts are similar around the world, though the human toll tends to be most devastating in poor neighborhoods and developing nations.
The scientists also found that the worldwide intensity of these extreme wet and dry events – a metric that combines extent, duration, and severity – is closely linked to global warming.
From 2015-2021 – seven of the nine warmest years in the modern record – the frequency of extreme wet and dry events was four per year, compared with three per year in the previous 13 years. This makes sense, say the authors, because warmer air causes more moisture to evaporate from Earth’s surface during dry events; warm air can also hold more moisture to fuel severe snowfall and rainfall events.
“The idea of climate change can be abstract. A couple of degrees warmer doesn’t sound like much, but water cycle impacts are tangible,” said Matt Rodell, study co-author and a hydrologist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “Global warming is going to cause more intense droughts and wet periods, which affects people, the economy, and agriculture around the world. Monitoring hydrological extremes is important for preparing for future events, mitigating their impacts, and adapting.”
This visualization shows extremes of the water cycle over a twenty-year period (2002-2021) based on observations from the GRACE and GRACE-FO satellites. Dry events are shown as red spheres and wet events as blue spheres, with earlier years being shown as lighter shades and later years as darker shades. The volume of the sphere is proportional to the intensity of the event, a quantity measured in cubic kilometer months. The plots at the bottom of the figure show that the total intensity of extreme events increased as global temperatures increased.
Credits: NASA’s Goddard Space Flight Center
Rodell and study co-author UMD Scientist Bailing Li studied 1,056 extreme wet and dry events from 2002 to 2021, as observed by the Gravity Recovery and Climate Experiment (GRACE) and GRACE-Follow-On (GRACE-FO) satellites. The satellites use precise measurements of Earth’s gravity field to detect water storage anomalies — specifically, how the amount of water stored in soils, aquifers, lakes, rivers, snow cover, and ice compares to normal.
“It’s like watching the level of the water in your bathtub,” Rodell said. “You can see how much it rises and falls without knowing the total amount of water in the tub.” Because GRACE and GRACE-FO provide a new map of water storage anomalies around the world every month, they provide a comprehensive view of the severity of hydrological events and how they evolve over time.
In their study, Rodell and Li applied an “intensity” metric that accounts for the severity, duration, and spatial extent of droughts and extreme wet events. They found the global total intensity of extreme events increased from 2002 to 2021, mirroring Earth’s rising temperatures over the same period.
By far the most intense event identified in the study was a pluvial that began in 2019 in central Africa and is still ongoing. It has caused the level of Lake Victoria to rise by more than one meter. A 2015-2016 drought in Brazil was the most intense dry event of the past two decades, leading to empty reservoirs, and water rationing across some Brazilian cities.
“Both events were associated with climate variability, but the Brazilian drought occurred in the warmest year on record (2016), reflecting the impact of global warming,” said Bailing Li, a University of Maryland hydrologist at Goddard. “The recent southwestern U.S. and southern Europe droughts were also some of the most intense events, in part, due to anthropogenic warming.”
“Global warming has had broad and profound impacts on terrestrial water storage, such as reduction of annual snow in high elevations and depletion of groundwater by people when surface waters are scarce,” Li added. “Reflecting these changes, GRACE data provide us a unique perspective of how hydrological extremes have been changing around the world.”