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Large
Methane Plumes Discovered on Laptev Continental Slope Boundary:
Evidence of Possible Methane Hydrate Release
(The Swedish Icebreaker Oden — now home to the 80 scientists and tons of equipment of the SWERUS 2014 research expedition aimed at measuring sea floor methane release throughout the Arctic this summer. Among the scientists leading the expedition is Igor Semiletov whose 2011 expedition discovered 1 kilometer wide plumes of methane issuing from the floor of the East Siberian Arctic Shelf. Image source: Commons.)
28 July, 2014
"SWERUS-C3
researchers have on earlier
expeditions documented extensive
venting of methane from the subsea system to the atmosphere over the
East Siberian Arctic Shelf. On this Oden
expedition we have gathered a strong team to assess these methane
releases in greater detail than ever before to substantially improve
our collective understanding of the methane sources and the
functioning of the system. This is information that is crucial if we
are to be able to provide scientific estimations of how these methane
releases may develop in the future (emphasis added). — Örjan
Gustafsson
*
* * * *
Over
the past few years, the Arctic has been experiencing an invasion.
Emerging
from the Gulf Stream, a pulse of warmer than normal water propagated
north past Iceland and into the Barents Sea. There, it dove beneath
the surface fresh water and retreating sea ice, plunging to a depth
of around 200-500 meters where it concentrated, lending heat to the
entire water column. Taking a right hand turn along the Siberian
Continental Shelf, it crossed through the mid water zones of the
Kara. Finally, it entered the Laptev and there it abutted against the
downward facing slopes of the submarine continental region.
As
the water temperatures at these depths warmed, researchers began to
wonder if they would trigger the destabilization of methane hydrate
stores locked in deeper waters along the shelf boundary. And,
now, a new expedition may have uncovered evidence that just such an
event is ongoing.
Methane
Hydrates and Troubling Releases from the East Siberian Arctic Shelf
Oceanic
methane hydrates form when methane upon or beneath the sea bed freeze
into a crystalline ice lattice. It is a hybrid water-methane mixture
that only remains stable at higher sub-sea pressures and lower
temperatures. Normally, oceanic hydrates form at great depth (about
600 meters or deeper) where a combination of high pressure and low
temperature are the prevailing environmental factor. But the colder
Arctic is a sometimes exception to this general rule.
In
recent years, deep ocean warming due to human caused climate change
has accelerated. It is feared that this warming may unlock vast
stores of methane laying frozen along the deep sea bed or in more
vulnerable continental shelf slope zones.
This
warming is also feared to have begun a process of methane release
along a unique submarine feature called the East Siberian Arctic
Shelf (ESAS). There rising temperatures are hypothesized to have sped
the thaw of submarine permafrost.
Frozen
permafrost stores biologically generate gaseous methane at depths of
10-80 meters. Methane hydrate stores are locked away at depths
starting at around 100 meters. Submerged beneath only a couple
hundred feet of water, these methane stores are much shallower and,
therefore, are in a naturally unstable zone.
The
East Siberian Sea zone is unique due to the fact that it was only
recently flooded, in geological terms. The frozen permafrost has only
rested beneath the Arctic Ocean waters since the end of the last ice
age and much of it remained frozen due to chill Arctic conditions.
But now, human-caused climate change is driving warmer and warmer
waters into the Arctic environment.
(Elevated atmospheric methane levels over East Siberian and Laptev Seas during October of 2013. Image source: Arctic News via Methane Tracker)
As
the warming progressed during the first decade of the 21st Century,
researchers observed what appeared to be an increasing release of
methane from these thawing permafrost stores. In 2011, plumes from
the sea bed stretching 1 kilometer across were observed by an Arctic
expedition headed by Igor Similetov and Natalia Shakova. It appeared
that the 250 to 500 gigatons of carbon locked in the ice in that
shallow ocean was destabilizing and releasing from the sea floor as
methane.
Now
it is estimated that about 17 megatons of methane from this store
vents through the shallow waters into the atmosphere each year. But
this may just be the start of a far larger emission.
Methane
Hydrate Release During Past Hothouse Events
Though
the ESAS carbon and methane store is arguably one of the most
vulnerable to human-caused warming, a far greater store of methane
hydrate is estimated to be locked in crystalline ice lattice
structures along the world’s continental slope systems and in the
world’s deep ocean environments. Since the Earth has been cooling
for the better part of 55 million years, a huge store of carbon as
methane is now thought to have accumulated there. In total, between
3,000 and 10,000 gigatons of carbon are estimated to be captured in
this vast store.
(Methane bubbles near the Laptev Sea surface as observed by the SWERUS expedition last week. These bubbles were issuing from what are thought to be destabilizing methane hydrates along the Outer Laptev Continental Slope zone. Image source: Stockholm University.)
Global
warming science, especially the science related to paleoclimate,
indicates that Earth Systems warming tends to dump a lot of heat into
the deep ocean. The atmosphere ocean-interface along the equator
warms and becomes salty due to enhanced evaporation. The warmer,
saltier water sinks, driving heat into the deep ocean. At the poles,
ice sheet melt sends out a wave of fresh water along the ocean
surface. The fresh water acts as an insulator between atmosphere and
water, locking the warm water beneath the surface and pushing it
toward the bottom. This process, called ocean stratification, is,
among other things, an ocean heat exchange machine that turns the
ocean bottom into a horrifically warm place.
We
would expect a similar process to be set in motion through human
warming.
Ultimately,
this combination of forces results in a collision of warm water with
frozen methane stores and serves as a mechanism for their
destabilization. If even a portion of this deep ocean methane hits
the air, it can further accelerate already rampant warming.
Today,
we may be at the start of just this kind of process.
Large
Methane Plumes Discovered Along The Laptev Slope Boundary
Last
week, large plumes of methane were found to be issuing from the outer
Laptev Sea floor at the border zone where the bottom climbs up to
meet the East Siberian Arctic Shelf. Researchers on the scientific
study vessel Oden found:
elevated
methane levels, about ten times higher than in background seawater,
[that] were documented … as we climbed up the steep continental
slope at stations in 500 and 250 m depth.
Expedition
researchers noted:
This
was somewhat of a surprise. While there has been much speculation of
the vulnerability of regular marine hydrates (frozen methane formed
due to high p [pressure] and low T [temperature]) along the Arctic
rim, very few actual observations of methane releases due to
collapsing Arctic upper slope marine hydrates have been made.
(An ice-free Laptev Sea on July 28, 2014. Last week, researchers discovered a kilometers wide plume of methane bubbling up from the Continental Shelf sea bed in these typically-frozen waters. Image source: LANCE-MODIS.)
Overall
the size of the release zone was quite large, covering several
kilometers of sea bed and including over 100 methane seepage sites:
Using
the mid-water sonar, we mapped out an area of several kilometers
where bubbles were filling the water column from depths of 200 to 500
m. During the preceding 48 h we have performed station work in two
areas on the shallow shelf with depths of 60-70m where we discovered
over 100 new methane seep sites.
Due
to the depth and location of the methane above the continental slope
zone, researchers hypothesize that the source of the methane is from
hydrate stores in the region.
It
is worth noting that though it is rare to observe methane releases
from the upper slope zone, current science has found destabilizing
hydrates in deep water off the US East Coast along the continental
shelf slope zone and in deep waters off Svalbard among other places.
In addition, satellite observation of the Arctic Ocean has recently
shown periods of high and above normal methane readings in the
Laptev, Kara and East Siberian Seas. Elevated atmospheric readings
have also appeared over the Nares Strait near Greenland. These are
all zones that have experienced substantial deep ocean warming over
the past few decades.
SWERUS
2014 is now heading toward ESAS waters where so many large
methane plumes were discovered in 2011. There, the expedition hopes
to use its impressive array of sensors and expertise to better define
and understand what appear to be large-scale but not yet catastrophic
methane releases underway there.
Links:
Hat
tip to TodaysGuestIs
Hat
tip to Colorado Bob
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