Findings alter the prevailing understanding of how marine life influences clouds
October 20, 2021
Stand on the ocean’s shore and take a big whiff of the salt spray and you will smell the unmistakably pungent scent of the sea. The ripe, almost rotting smell? That’s sulfur.
Marine plankton breathe more than 20 million tons of sulfur into the air every year, mostly in the form of dimethyl sulfide, or DMS. In the air, this chemical can transform into sulfuric acid, which helps produce clouds by providing a site for water droplets to form. Over the scale of the world’s oceans, this process affects the entire climate.
But U.S. National Science Foundation-funded research from the University of Wisconsin–Madison and other institutions reveals that more than one-third of the DMS emitted from the sea can’t help new clouds form because it is lost to the clouds themselves. The new findings significantly alter the understanding of how marine life influences clouds, and may change the way scientists predict how cloud formation responds to changes in the oceans.
By reflecting sunlight back into space and controlling rainfall, clouds play a significant role in global climate. Accurately predicting them is essential to understanding the effects of climate change.
“It turns out that the story of cloud formation was really incomplete,” says Tim Bertram of UW-Madison, senior author of the new report. “Over the last three or four years, we’ve been questioning parts of that story, both through laboratory experiments and with large-scale field experiments. Now we can better connect the dots between what’s emitted from the ocean and how these particulates that encourage cloud formation form.”
The results were published in Proceedings of the National Academy of Sciences.
“This research group is tracking down the connection of biofluxes to the formation of marine clouds, taking us one more step toward understanding Earth’s changing climate,” says Chungu Lu, a program director in NSF’s Division of Atmospheric and Geospace Sciences.
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Source: NSF News