Adalberto Rios Lanz/Sexto Sol
Mist and clouds above the Amazon are formed in part by the vegetation
below
When you mess with the Amazon rainforest you mess with a lot of things —
2.5 million species of insects, 40,000 species of plants, 1,300 species of
birds, and those are only the known ones. The 1.4 billion of acres of thriving,
sprawling biology that cover the Amazon help drive the very metabolism of a
continent. And now it appears that the rainforest is at least partly
responsible for something else: the Amazonian clouds themselves. Clear-cut the
land and you could, in effect, clear-cut the sky.
That improbable idea comes courtesy of a paper just released in the journal Science, the product of work done
by researchers at the Max Planck Institute for Chemistry in
Mainz, Germany. The clouds in the Amazon, just like everywhere else, consist of
water vapor clinging to tiny clumps of carbon compounds. In forested areas, the
carbon compounds are byproducts of plants’ metabolism; in populated areas, they
are often from human pollution. Most of the time, atmospheric chemists can see
the carbon clumping taking place; when the microscopic bits reach a certain
size, they are able to attract and hold water. In the Amazon, the clumps seem
to appear out of nowhere, nearly fully formed. No one has ever been able to
catch them in the act of coming together.
(PHOTOS: Brazil’s Controversial Belo Monte Dam)
(PHOTOS: Brazil’s Controversial Belo Monte Dam)
Max Planck graduate student Christopher Pohlker traveled to a pristine
stretch of forest in Brazil to see if he could solve the riddle. He gathered a
bit of rainforest air, using an instrument that sucks a sample through a fine
nozzle and sprays it onto a ceramic square half a millimeter on each side,
where any microscopic airborne particles get stuck. To figure out the chemical
make-up of those particles, he and his colleagues brought the squares to Lawrence Berkeley
National Laboratory in California and
placed them in the facility’s synchrotron, where X-rays of varying energies
were fired at the collected specks. The specific frequencies that were absorbed
could reveal the samples’ chemical makeup.
What the researchers found was a mix of carbon compounds, plus one other
thing: potassium — and that told them a lot. Potassium salts appear to be good
at getting carbon compounds to stick together. The larger a carbon cluster was,
the larger the ratio of carbon compounds to potassium within it, suggesting
that just a certain amount of potassium was needed to get the accretion process
started, and after that the carbon compounds kept piling on of their own
accord. That, in turn, would get water droplets forming.
(More: Amazonia: What’s Happening to the World’s Biggest Rainforest?)
(More: Amazonia: What’s Happening to the World’s Biggest Rainforest?)
The real surprise was the source of the potassium. Forest fires often
release the element into the air, but there were none burning when Pohlker took
the samples. “Since we can rule out the burning source in our samples,” he
says, “the other source seemed to be the biosphere itself.” In other words, the
forest.
Plants and fungi can release potassium into the air under certain
conditions. Fungi in particular are veritable fountains of the stuff: when they
shoot out their spores, they also spray out a potassium-rich fluid. Biologists
working with leaf molds and other fungi in the lab had noticed this, and
atmospheric chemists had noticed that there seemed to be a lot of potassium floating
above the Amazon in the wet season. Pohlker’s adviser, chemist Meinrat Andreae,
in fact recently reported that a third of the Earth’s land surface is probably
covered with microscopic fungi. But until now, no one had linked potassium from
fungi to cloud formation. “We think the residue of these droplets is what we
are observing,” Pohlker says. “It’s really impressive.”
Pohlker, Andreae, and their colleagues ran the numbers and found that
the amount of potassium particles released from microscopic fungi in the lab
was indeed enough to account for the concentration of potassium they observed
in their samples. But there are still some crucial experiments left to do:
specifically, they have not yet actually verified that the microscopic fungi
living on the forest trees in the Amazon are in fact releasing the potassium
they see in the air. “What we’re still lacking is a demonstration that if you
go to a plant in the Amazon and put a plastic bag around it, you’ll see these
particles coming off,” Andreae says. “That’s one of the things we want to do
next.”
Even when that’s done, it’s not clear everyone will be sold on the new
findings — or at least on their thoroughness. “Are these particles only
relevant directly over the rain forest, or are they lofted by convection and
transported to surrounding regions?” wrote Yale University professor and climate modeler Trude Storelvmo in an email. Yet another
topic for future research is the question of whether the Amazon is the only rainforest
that gets the potassium cycle going this way or if other — perhaps all —
rainforests do it. What’s settled science now, however, is that just as the
Amazon is dependent on the rain and sunlight provided by the sky, the sky is
dependent on the nourishment from the forest. The circle of life just added
another ring.
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