The money paragraph is toward the end, highlighted.
Science Daily, June 11, 2013 — Flying low and slow above the
wild, pristine terrain of Alaska's North Slope in a specially
instrumented NASA plane, research scientist Charles Miller of NASA's Jet
Propulsion Laboratory, Pasadena, Calif., surveys the endless whiteness
of tundra and frozen permafrost below. On the horizon, a long, dark line
appears. The plane draws nearer, and the mysterious object reveals
itself to be a massive herd of migrating caribou, stretching for miles.
It's a sight Miller won't soon forget.
Seeing those caribou marching single-file across the tundra puts what
we're doing here in the Arctic into perspective," said Miller,
principal investigator of the Carbon in Arctic Reservoirs Vulnerability
Experiment (CARVE), a five-year NASA-led field campaign studying how
climate change is affecting the Arctic's carbon cycle.
"The Arctic is critical to understanding global climate," he said.
"Climate change is already happening in the Arctic, faster than its
ecosystems can adapt. Looking at the Arctic is like looking at the
canary in the coal mine for the entire Earth system."
Aboard the NASA C-23 Sherpa aircraft from NASA's Wallops Flight
Facility, Wallops Island, Va., Miller, CARVE Project Manager Steve
Dinardo of JPL and the CARVE science team are probing deep into the
frozen lands above the Arctic Circle. The team is measuring emissions of
the greenhouse gases carbon dioxide and methane from thawing permafrost
-- signals that may hold a key to Earth's climate future.
What Lies Beneath
Permafrost (perennially frozen) soils underlie much of the Arctic.
Each summer, the top layers of these soils thaw. The thawed layer varies
in depth from about 4 inches (10 centimeters) in the coldest tundra
regions to several yards, or meters, in the southern boreal forests.
This active soil layer at the surface provides the precarious foothold
on which Arctic vegetation survives. The Arctic's extremely cold, wet
conditions prevent dead plants and animals from decomposing, so each
year another layer gets added to the reservoirs of organic carbon
sequestered just beneath the topsoil.
Over hundreds of millennia, Arctic permafrost soils have accumulated
vast stores of organic carbon -- an estimated 1,400 to 1,850 petagrams
of it (a petagram is 2.2 trillion pounds, or 1 billion metric tons).
That's about half of all the estimated organic carbon stored in Earth's
soils. In comparison, about 350 petagrams of carbon have been emitted
from all fossil-fuel combustion and human activities since 1850. Most of
this carbon is located in thaw-vulnerable topsoils within 10 feet (3
meters) of the surface.
But, as scientists are learning, permafrost -- and its stored carbon
-- may not be as permanent as its name implies. And that has them
concerned.
"Permafrost soils are warming even faster than Arctic air
temperatures -- as much as 2.7 to 4.5 degrees Fahrenheit (1.5-2.5 C) in just the past 30 years," Miller said. "As heat from
Earth's surface penetrates into permafrost, it threatens to mobilize
these organic carbon reservoirs and release them into the atmosphere as
carbon dioxide and methane, upsetting the Arctic's carbon balance and
greatly exacerbating global warming."
Current climate models do not adequately account for the impact of
climate change on permafrost and how its degradation may affect regional
and global climate. Scientists want to know how much permafrost carbon
may be vulnerable to release as Earth's climate warms, and how fast it
may be released.
CARVing Out a Better Understanding of Arctic Carbon
Enter CARVE. Now in its third year, this NASA Earth Ventures program
investigation is expanding our understanding of how the Arctic's water
and carbon cycles are linked to climate, as well as what effects fires
and thawing permafrost are having on Arctic carbon emissions. CARVE is
testing hypotheses that Arctic carbon reservoirs are vulnerable to
climate warming, while delivering the first direct measurements and
detailed regional maps of Arctic carbon dioxide and methane sources and
demonstrating new remote sensing and modeling capabilities. About two
dozen scientists from 12 institutions are participating.
"The Arctic is warming dramatically -- two to three times faster than
mid-latitude regions -- yet we lack sustained observations and accurate
climate models to know with confidence how the balance of carbon among
living things will respond to climate change and related phenomena in
the 21st century," said Miller. "Changes in climate may trigger
transformations that are simply not reversible within our lifetimes,
potentially causing rapid changes in the Earth system that will require
adaptations by people and ecosystems."
The CARVE team flew test flights in 2011 and science flights in 2012.
This April and May, they completed the first two of seven planned
monthly campaigns in 2013, and they are currently flying their June
campaign.
Each two-week flight campaign across the Alaskan Arctic is designed
to capture seasonal variations in the Arctic carbon cycle: spring thaw
in April/May, the peak of the summer growing season in June/July, and
the annual fall refreeze and first snow in September/October. From a
base in Fairbanks, Alaska, the C-23 flies up to eight hours a day to
sites on Alaska's North Slope, interior and Yukon River Valley over
tundra, permafrost, boreal forests, peatlands and wetlands.
The C-23 won't win any beauty contests -- its pilots refer to it as
"a UPS truck with a bad nose job." Inside, it's extremely noisy -- the
pilots and crew wear noise-cancelling headphones to communicate. "When
you take the headphones off, it's like being at a NASCAR race," Miller
quipped.
But what the C-23 lacks in beauty and quiet, it makes up for in
reliability and its ability to fly "down in the mud," so to speak. Most
of the time, it flies about 500 feet (152 meters) above ground level,
with periodic ascents to higher altitudes to collect background data.
Most airborne missions measuring atmospheric carbon dioxide and methane
do not fly as low.
"CARVE shows you need to fly very close to the
surface in the Arctic to capture the interesting exchanges of carbon
taking place between Earth's surface and atmosphere," Miller said.
Onboard the plane, sophisticated instruments "sniff" the atmosphere
for greenhouse gases. They include a very sensitive spectrometer that
analyzes sunlight reflected from Earth's surface to measure atmospheric
carbon dioxide, methane and carbon monoxide. This instrument is an
airborne simulator for NASA's Orbiting Carbon Observatory-2 (OCO-2)
mission to be launched in 2014. Other instruments analyze air samples
from outside the plane for the same chemicals. Aircraft navigation data
and basic weather data are also collected. Initial data are delivered to
scientists within 12 hours. Air samples are shipped to the University
of Colorado's Institute for Arctic and Alpine Research Stable Isotope
Laboratory and Radiocarbon Laboratory in Boulder for analyses to
determine the carbon's sources and whether it came from thawing
permafrost.
Much of CARVE's science will come from flying at least three years,
Miller says. "We are showing the power of using dependable, low-cost
prop planes to make frequent, repeat measurements over time to look for
changes from month to month and year to year."
Ground observations complement the aircraft data and are used to
calibrate and validate them. The ground sites serve as anchor points for
CARVE's flight tracks. Ground data include air samples from tall towers
and measurements of soil moisture and temperature to determine whether
soil is frozen, thawed or flooded.
A Tale of Two Greenhouse Gases
It's important to accurately characterize the soils and state of the
land surfaces. There's a strong correlation between soil characteristics
and release of carbon dioxide and methane. Historically, the cold, wet
soils of Arctic ecosystems have stored more carbon than they have
released. If climate change causes the Arctic to get warmer and drier,
scientists expect most of the carbon to be released as carbon dioxide.
If it gets warmer and wetter, most will be in the form of methane.
The distinction is critical. Molecule per molecule, methane is 22
times more potent as a greenhouse gas than carbon dioxide on a 100-year
timescale, and 105 times more potent on a 20-year timescale. If just 1% of the permafrost carbon released over a short time period is
methane, it will have the same greenhouse impact as the 99% that
is released as carbon dioxide. Characterizing this methane-to-carbon
dioxide ratio is a major CARVE objective.
There are other correlations between Arctic soil characteristics and
the release of carbon dioxide and methane. Variations in the timing of
spring thaw and the length of the growing season have a major impact on
vegetation productivity and whether high northern latitude regions
generate or store carbon.
CARVE is also studying wildfire impacts on the Arctic's carbon cycle.
Fires in boreal forests or tundra accelerate the thawing of permafrost
and carbon release. Detailed fire observation records since 1942 show
the average annual number of Alaska wildfires has increased, and fires
with burn areas larger than 100,000 acres are occurring more frequently,
trends scientists expect to accelerate in a warming Arctic. CARVE's
simultaneous measurements of greenhouse gases will help quantify how
much carbon is released to the atmosphere from fires in Alaska -- a
crucial and uncertain element of its carbon budget.
Early Results
The CARVE science team is busy analyzing data from its first full
year of science flights. What they're finding, Miller said, is both
amazing and potentially [delete "potentially"] troubling.
"Some of the methane and carbon dioxide concentrations we've measured
have been large, and we're seeing very different patterns from what
models suggest," Miller said. "We saw large, regional-scale episodic
bursts of higher-than-normal carbon dioxide and methane in interior
Alaska and across the North Slope during the spring thaw, and they
lasted until after the fall refreeze. To cite another example, in July
2012 we saw methane levels over swamps in the Innoko Wilderness that
were 650 parts per billion higher than normal background levels. That's
similar to what you might find in a large city."
Ultimately, the scientists hope their observations will indicate
whether an irreversible permafrost tipping point may be near at hand.
While scientists don't yet believe the Arctic has reached that tipping
point, no one knows for sure. "We hope CARVE may be able to find that
'smoking gun,' if one exists," Miller said.
Other institutions participating in CARVE include City College of New
York; the joint University of Colorado/National Oceanic and Atmospheric
Administration's Cooperative Institute for Research in Environmental
Sciences, Boulder, Colo.; San Diego State University; University of
California, Irvine; California Institute of Technology, Pasadena;
Harvard University, Cambridge, Mass.; University of California,
Berkeley; Lawrence Berkeley National Laboratory, Berkeley, Calif.;
University of California, Santa Barbara; NOAA's Earth System Research
Laboratory, Boulder, Colo.; and University of Melbourne, Victoria,
Australia.
http://www.sciencedaily.com/releases/2013/06/130611144338.htm
No comments:
Post a Comment