In years with less frequent but more concentrated rainfall, plants in drier environments like the U.S. Southwest were more likely to thrive. In humid ecosystems like the Central American rainforest, vegetation tended to fare worse, possibly because it could not tolerate the longer dry spells.
Scientists have previously estimated that almost half of the world's vegetation is driven primarily by how much rain falls in a year. Less well understood is the role of day-to-day variability, said lead author Andrew Feldman, a hydrologist and ecosystem scientist at NASA's Goddard Space Flight Center in Greenbelt, Maryland. Shifting precipitation patterns are producing stronger rainstorms - with longer dry spells in between - compared to a century ago.
"You can think of it like this: if you have a house plant, what happens if you give it a full pitcher of water on Sunday versus a third of a pitcher on Monday, Wednesday, and Friday?" said Feldman. Scale that to the size of the U.S. Corn Belt or a rainforest and the answer could have implications for crop yields and ultimately how much carbon dioxide plants remove from the atmosphere.
They found that plants across 42% of Earth's vegetated land surface were sensitive to daily rainfall variability. Of those, a little over half fared better - often showing increased growth - in years with fewer but more intense wet days. These include croplands as well as drier landscapes like grasslands and deserts.
In contrast, broadleaf (e.g., oak, maple, and beech) forests and rainforests in lower and middle latitudes tended to fare worse under those conditions. The effect was especially pronounced in Indo-Pacific rainforests, including in the Philippines and Indonesia.
Statistically, daily rainfall variability was nearly as important as annual rainfall totals in driving growth worldwide.
To gauge plant response day to day, the researchers calculated how green an area appeared in satellite imagery. "Greenness", also known asthe Normalized Difference Vegetation Index, is commonly used to estimate vegetation density and health. They also tracked a faint reddish light that plants emit during photosynthesis, when a plant absorbs sunlight to convert carbon dioxide and water into food, its chlorophyll "leaks" unused photons. This faint light is called solar-induced fluorescence, and it's a telltale sign of flourishing vegetation.
Not visible bythe naked eye, plant fluorescence can be detected by instruments aboard satellites such as NASA's Orbiting Carbon Observatory-2 (OCO-2). Launched in 2014, OCO-2 has observed the U.S. Midwest fluorescing strongly during the growing season.
Feldman said the findings highlight the vital role that plants play in moving carbon around Earth - a process called the carbon cycle. Vegetation, including crops, forests, and grasslands, forms a vast carbon "sink," absorbing excess carbon dioxide from the atmosphere.
"A finer understanding of how plants thrive or decline day to day, storm by storm, could help us better understand their role in that critical cycle," Feldman said.
The study also included researchers from NASA's Jet Propulsion Laboratory in Southern California, Stanford University, Columbia University, Indiana University, and the University of Arizona.
Related Links
Orbiting Carbon Observatory-2
Earth Observation News - Suppiliers, Technology and Application
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