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June 30, 2016
from
PHYS Website
A false-color image
showing ozone concentrations
above Antarctica on
Oct. 2, 2015.
Credit: NASA/Goddard
Space Flight Center
Scientists at MIT and elsewhere have identified the "first
fingerprints of healing" of the Antarctic ozone layer, published
today (Emergence
of Healing in the Antarctic Ozone Layer) in the journal
Science.
The team found that the September ozone hole has shrunk by more than
4 million square kilometers - about half the area of the contiguous
United States - since 2000, when ozone depletion was at its peak.
The team also showed for the first time that this recovery has
slowed somewhat at times, due to the effects of volcanic eruptions
from year to year.
Overall, however, the ozone hole appears
to be on a healing path.
The authors used "fingerprints" of the ozone changes with season and
altitude to attribute the ozone's recovery to the continuing decline
of atmospheric
chlorine originating from
chlorofluorocarbons (CFCs).
These chemical compounds were once
emitted by dry cleaning processes, old refrigerators, and aerosols
such as hairspray.
In 1987, virtually every country in the
world signed on to
the Montreal Protocol in a
concerted effort to ban the use of CFCs and repair the ozone hole.
"We can now be confident that the
things we've done have put the planet on a path to heal," says
lead author Susan Solomon, the Ellen Swallow Richards Professor
of Atmospheric Chemistry and Climate Science at MIT.
"Which is pretty good for us, isn't
it? Aren't we amazing humans, that we did something that created
a situation that we decided collectively, as a world, 'Let's get
rid of these molecules'? We got rid of them, and now we're
seeing the planet respond."
Susan Solomon's co-authors
include Diane Ivy, research scientist in the Department of
Earth, Atmospheric and Planetary Sciences, along with researchers at
the National Center for Atmospheric Research in Boulder, Colorado,
and the University of Leeds in the U.K.
Signs before
spring
The ozone hole was first discovered using ground-based data that
began in the 1950s.
Around the mid-1980s, scientists from
the British Antarctic survey noticed that the October total ozone
was dropping. From then on, scientists worldwide typically tracked
ozone depletion using October measurements of Antarctic ozone.
Ozone is sensitive not just to chlorine, but also to temperature and
sunlight.
Chlorine eats away at ozone, but only if
light is present and if the atmosphere is cold enough to create
polar stratospheric clouds on which chlorine chemistry can occur - a
relationship that Solomon was first to characterize in 1986.
Measurements have shown that ozone
depletion starts each year in late August, as
Antarctica emerges from its dark
winter, and the hole is fully formed by early October.
Solomon and her colleagues believed they would get a clearer picture
of chlorine's effects by looking earlier in the year, at ozone
levels in September, when cold winter temperatures still prevail and
the ozone hole is opening up.
The team showed that as the chlorine has
decreased, the rate at which the hole opens up in September has
slowed down.
"I think people, myself included,
had been too focused on October, because that's when the ozone
hole is enormous, in its full glory," Solomon says.
"But October is also subject to the
slings and arrows of other things that vary, like slight changes
in meteorology. September is a better time to look because
chlorine chemistry is firmly in control of the rate at which the
hole forms at that time of year.
That point hasn't really been made
strongly in the past."
A healing
trend
The researchers tracked the yearly opening of the Antarctic ozone
hole in the month of September, from 2000 to 2015.
They analyzed ozone measurements taken
from weather balloons and satellites, as well as satellite
measurements of sulfur dioxide emitted by volcanoes, which can also
enhance ozone depletion. And, they tracked meteorological changes,
such as temperature and wind, which can shift the ozone hole back
and forth.
They then compared their yearly September ozone measurements with
model simulations that predict ozone levels based on the amount of
chlorine that scientists have estimated to be present in the
atmosphere from year to year.
The researchers found that the ozone
hole has declined compared to its peak size in 2000, shrinking by
more than 4 million square kilometers by 2015.
They further found that this decline
matched the model's predictions, and that more than half the
shrinkage was due solely to the reduction in atmospheric chlorine.
"It's been interesting to think
about this in a different month, and looking in September was a
novel way," Ivy says. "It showed we can actually see a chemical
fingerprint, which is sensitive to the levels of chlorine,
finally emerging as a sign of recovery."
The team did observe an important
outlier in the trend:
In 2015, the ozone hole reached a
record size, despite the fact that atmospheric chlorine
continued to drop.
In response, scientists had questioned
whether any healing could be determined.
Going through the data, however, Solomon
and her colleagues realized that the 2015 spike in ozone depletion
was due primarily to the eruption of the Chilean
volcano Calbuco.
Volcanoes don't inject significant
chlorine into the stratosphere but they do increase small particles,
which increase the amount of polar stratospheric clouds with which
the human-made chlorine reacts.
As chlorine levels continue to dissipate from the atmosphere,
Solomon sees no reason why, barring future volcanic eruptions, the
ozone hole shouldn't shrink and eventually close permanently by
midcentury.
"What's exciting for me personally
is, this brings so much of my own work over 30 years full
circle," says Solomon, whose research into chlorine and ozone
spurred the Montreal Protocol.
"Science was helpful in showing the
path, diplomats and countries and industry were incredibly able
in charting a pathway out of these molecules, and now we've
actually seen the planet starting to get better. It's a
wonderful thing."
Key facts
-
Scientists from the
British Antarctic Survey
discovered in the mid-1980s that the October total ozone was
dropping. From then on, scientists worldwide typically
tracked ozone depletion using October measurements of
Antarctic ozone
-
Ozone is sensitive not just to
chlorine, but also to temperature and sunlight. Chlorine
eats away at ozone, but only if light is present and if the
atmosphere is cold enough to create polar stratospheric
clouds on which chlorine chemistry can occur
-
Measurements have shown that
ozone depletion starts each year in late August, as
Antarctica emerges from its dark winter, and the hole is
fully formed by early October
-
The researchers focused on
September because chlorine chemistry is firmly in control of
the rate at which the hole forms at that time of year, so as
chlorine has decreased, the rate of depletion has slowed
down
-
They tracked the yearly opening
of the Antarctic ozone hole each September from 2000 to
2015, analyzing ozone measurements taken from weather
balloons and satellites, as well as satellite measurements
of sulphur dioxide emitted by volcanoes, which can also
enhance ozone depletion. And, they tracked meteorological
changes, such as temperature and wind, which can shift the
ozone hole back and forth.
-
They then compared yearly
September ozone measurements with computer simulations that
predict ozone levels based on the amount of chlorine
estimated to be present in the atmosphere from year to year.
The researchers found that the ozone hole has declined
compared to its peak size in 2000. They further found that
this decline matched the model's predictions, and that more
than half the shrinkage was due solely to the reduction in
atmospheric chlorine and bromine
-
Chlorofluorocarbon chemicals (CFCs)
last for up to 100 years in the atmosphere, so it will be
many years before they disappear completely
The reason there is an ozone hole in the Antarctic is that
it is the coldest place on Earth - it is so cold that clouds
form in the Antarctic stratosphere. Those clouds provide
particles, surfaces on which the man-made chlorine from the
chlorofluorocarbons reacts. This special chemistry is what
makes ozone depletion worse in the Antarctic.
More information: "Emergence
of Healing in the Antarctic Ozone Layer," by S. Solomon
et al. Science, DOI: 10.1126/science.aae0061.
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