Posts
"Virtually
all the climate models assume there's no or very little emission of
methane when the ground is frozen," Oechel said. "That
assumption is incorrect."
Methane Emissions in Arctic Cold Season Higher Than Expected
Methane Emissions in Arctic Cold Season Higher Than Expected
Half
of Alaska's methane emissions occur in winter -- mostly during times
when soil temperatures are poised near freezing. Credit:
NASA/JPL-Caltech
NASA,
21
December, 2015
The
amount of methane gas escaping from the ground during the long cold
period in the Arctic each year and entering Earth's atmosphere is
likely much higher than estimated by current carbon cycle models,
concludes a major new study led by San Diego State University and
including scientists from NASA's Jet Propulsion Laboratory, Pasadena,
California.
After
Four Years, CARVE Makes Its Last Arctic Flight
On Nov. 12 of this year, NASA's Carbon in Arctic Reservoirs Vulnerability Experiment (CARVE) completed its final aircraft flight. During its four-year campaign, CARVE accumulated more than 1,000 science flight hours of measurements over Alaska, collecting data on important greenhouse gases during seven to eight months of each year.
The permafrost (perennially frozen) and peat soils of Arctic and boreal (northern region) ecosystems are the single largest reservoir of terrestrial carbon, containing twice as much carbon as is currently present in the atmosphere. As Arctic soils thaw and fires proliferate due to global warming, accentuated at high latitudes, the risk that the carbon will be released to the atmosphere continues to increase. CARVE collected detailed measurements of carbon dioxide, carbon monoxide and methane over every Alaskan Arctic and boreal ecosystem.
The end of such a long mission is bittersweet, says Principal Investigator Charles Miller of NASA's Jet Propulsion Laboratory, Pasadena, California. "We've made lots of friends in Alaska. After four years, it's almost like another university education." The team has been making preliminary data available after each year's campaign, and now, Miller says, "We have a few months to make sure we've got all data calibrated, analyzed and quality controlled to the best of our ability, and then it will go to the terrestrial ecology Distributed Active Archive Center at Oak Ridge [National Laboratory, Tennessee]." In spring 2016, all four years of data and the team's supporting analysis and modeling results will be posted and freely available to interested users.
On Nov. 12 of this year, NASA's Carbon in Arctic Reservoirs Vulnerability Experiment (CARVE) completed its final aircraft flight. During its four-year campaign, CARVE accumulated more than 1,000 science flight hours of measurements over Alaska, collecting data on important greenhouse gases during seven to eight months of each year.
The permafrost (perennially frozen) and peat soils of Arctic and boreal (northern region) ecosystems are the single largest reservoir of terrestrial carbon, containing twice as much carbon as is currently present in the atmosphere. As Arctic soils thaw and fires proliferate due to global warming, accentuated at high latitudes, the risk that the carbon will be released to the atmosphere continues to increase. CARVE collected detailed measurements of carbon dioxide, carbon monoxide and methane over every Alaskan Arctic and boreal ecosystem.
The end of such a long mission is bittersweet, says Principal Investigator Charles Miller of NASA's Jet Propulsion Laboratory, Pasadena, California. "We've made lots of friends in Alaska. After four years, it's almost like another university education." The team has been making preliminary data available after each year's campaign, and now, Miller says, "We have a few months to make sure we've got all data calibrated, analyzed and quality controlled to the best of our ability, and then it will go to the terrestrial ecology Distributed Active Archive Center at Oak Ridge [National Laboratory, Tennessee]." In spring 2016, all four years of data and the team's supporting analysis and modeling results will be posted and freely available to interested users.
The
study included a team comprising ecologists Walter Oechel (SDSU and
Open University, Milton Keynes, United Kingdom) and Donatella Zona
(SDSU and the University of Sheffield, United Kingdom) and scientists
from JPL; Harvard University, Cambridge, Massachusetts; the National
Oceanic and Atmospheric Administration, Boulder, Colorado; and the
University of Montana, Missoula. The team found that far more methane
is escaping from Arctic tundra during the cold months when the soil
surface is frozen (generally from September through May), and from
upland tundra, than prevailing assumptions and carbon cycle models
previously assumed. In fact, they found that at least half of the
annual methane emissions occur in the cold months, and that drier,
upland tundra can be a larger emitter of methane than wet tundra. The
findings challenge critical assumptions in current global climate
models. The results are published this week in the Proceedings of the
National Academy of Sciences.
Methane
is a potent greenhouse gas that contributes to atmospheric warming,
and is approximately 25 times more potent per molecule than carbon
dioxide over a 100-year period. Methane trapped in the Arctic tundra
comes primarily from microbial decomposition of organic matter in
soil that thaws seasonally. This methane naturally seeps out of the
soil over the course of the year, but scientists worry that climate
change could lead to the release of even larger emissions from
organic matter that is currently stabilized in a deep, frozen soil
layer called permafrost.
Over
the past several decades, scientists have used specialized
instruments to accurately measure methane emissions in the Arctic and
incorporated those results into global climate models. However,
almost all of these measurements have been obtained during the
Arctic's short summer. The region's long, brutal cold period, which
accounts for between 70 and 80 percent of the year, has been largely
"overlooked and ignored," according to Oechel. Most
researchers, he said, figured that because the ground is frozen solid
during the cold months, methane emissions practically shut down for
the winter.
"Virtually
all the climate models assume there's no or very little emission of
methane when the ground is frozen," Oechel said. "That
assumption is incorrect."
The
water trapped in the soil doesn't freeze completely even below 32
degrees Fahrenheit (0 degrees Celsius), he explained. The top layer
of the ground, known as the active layer, thaws in the summer and
refreezes in the winter, and it experiences a kind of sandwiching
effect as it freezes. When temperatures are right around 32 degrees
Fahrenheit -- the so-called "zero curtain" -- the top and
bottom of the active layer begin to freeze, while the middle remains
insulated. Microorganisms in this unfrozen middle layer continue to
break down organic matter and emit methane many months into the
Arctic's cold period each year.
Just
how much methane is emitted during the Arctic winter? To find out,
Oechel and Zona oversaw the upgrade of five sampling towers to allow
them to operate continuously year-round above the Arctic Circle in
Alaska. The researchers recorded methane emissions from these sites
over two summer-fall-winter cycles between June 2013 and January
2015. The arduous task required highly specialized instruments that
had to operate continuously and autonomously through extreme cold for
months at a time. They developed a de-icing system that eliminated
biases in the measurement and that was only activated when needed to
maintain operation of the instruments down to minus 40 degrees
Fahrenheit (minus 40 degrees Celsius).
After
analyzing the data, the research team found a major portion of
methane emissions during the cold season were observed when
temperatures hovered near the zero curtain.
"This
is extremely relevant for the Arctic ecosystem, as the zero curtain
period continues from September until the end of December, lasting as
long or longer than the entire summer season," said Zona, the
study's first author. "These results are opposite of what
modelers have been assuming, which is that the majority of the
methane emissions occur during the warm summer months while the
cold-season methane contribution is nearly zero."
Surprisingly,
the researchers also found that during the cold seasons they studied,
the relative methane emissions were higher at the drier, upland
tundra sites than at wetland sites, contradicting yet another
longstanding assumption about Arctic methane emissions. Upland tundra
was previously assumed to be a negligible contributor of methane,
Zona said, adding that the freezing of the surface inhibits methane
oxidation, resulting in significant net methane emissions during the
fall and winter. Plants act like chimneys, facilitating the escape
through the frozen layer to the atmosphere. The highest annual
emissions were observed in the upland site in the foothills of the
Brooks Range, where warm soils and a deep active layer resulted in
high rates of methane production.
To
complement and verify the on-the-ground study, the University of
Montana's John Kimball and his team used microwave sensor
measurements from the AMSR-E instrument aboard NASA's Aqua satellite
to develop regional maps of surface water cover, including the
timing, extent and duration of seasonal flooding and drying of the
region's wetlands.
"We
were able to use the satellite data to show that the upland tundra
areas that appear to be the larger methane sources from the
on-the-ground instruments, account for more than half of all of the
tundra in Alaska," Kimball said.
Finally,
to test whether their site-specific sampling was representative of
methane emissions across the Arctic, the researchers compared their
results to measurements recorded during aircraft flights over the
region made by NASA's Carbon in Arctic Reservoirs Vulnerability
Experiment (CARVE).
"CARVE
flights were designed to cover as much of the year as feasible,"
said CARVE Principal Investigator Charles Miller of JPL. "It was
a challenging undertaking, involving hundreds of hours of flying in
difficult conditions."
The
data from the SDSU sites were well aligned with the larger-scale
aircraft measurements, Zona said.
"CARVE
aircraft measurements of atmospheric methane show that large areas of
Arctic tundra and boreal forest continue to emit methane to the
atmosphere at high rates, long after the surface soil freezes,"
said Róisín Commane of Harvard University, who helped acquire and
analyze the aircraft data.
Oechel
and Zona stressed the importance for modelers to have good baseline
data on methane emissions and to adjust their models to account for
Arctic cold-season methane emissions as well as the contributions of
non-wetland areas, including upland tundra.
"It
is now time to work more closely with climate modelers and assure
these observations are used to improve model predictions, and refine
our prediction of the global methane budget," Zona said.
It
is particularly important, Oechel added, for models to get methane
output right because the gas is a major driver of atmospheric
warming. "If you don't have the mechanisms right, you won't be
able to make predictions into the future based on anticipated climate
conditions," he said.
Steven
Wofsy of Harvard University added, "Now that we know how
important the winter is to the methane budget, we are working to
determine the long-term trends in greenhouse emissions from tundra
and their sensitivity to winter warming."
This
research has been funded by the National Science Foundation, NASA and
the Department of Energy.
SDSU;
JPL; Harvard University; the University of Montana; the University of
Sheffield; the National Research Council (CNR) of Italy; the
University of Helsinki; the University of Colorado, Boulder;
Atmospheric and Environmental Research, Lexington, Massachusetts; the
University of Alaska, Fairbanks; Dalhousie University, Halifax, Nova
Scotia, Canada; NOAA; and Open University all contributed to the
study.
NASA
uses the vantage point of space to increase our understanding of our
home planet, improve lives and safeguard our future. NASA develops
new ways to observe and study Earth's interconnected natural systems
with long-term data records. The agency freely shares this unique
knowledge and works with institutions around the world to gain new
insights into how our planet is changing.
More
information on CARVE:
More
information about NASA's Earth science activities:
Media
Contact
Alan
Buis
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-0474
Alan.buis@jpl.nasa.gov
Beth Downing Chee
San Diego State University, San Diego
619-594-4563
bchee@mail.sdsu.edu
2015-383
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-0474
Alan.buis@jpl.nasa.gov
Beth Downing Chee
San Diego State University, San Diego
619-594-4563
bchee@mail.sdsu.edu
2015-383
No comments:
Post a Comment
Note: only a member of this blog may post a comment.