Arctic News

Saturday, November 16, 2013

More Methane as Sea Ice thins

The image below shows methane readings of 1950 ppb and higher, as at November 15, 2013, p.m., close to sea level. The image also shows sea ice concentration, as at November 7, 2013, i.e. the most recent SSMIS data available on methanetracker.

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The image shows huge amounts of methane rising from the seafloor along the fault line that crosses the Arctic Ocean. The image also shows huge amounts of methane over thinner parts of the sea ice. To illustrate this further, the November 15, 2013, Naval Research Laboratory image is added below, showing ice thickness based on the most recent sea ice data.

The image below zooms in on the large amounts of methane, stretching out all the way from the Beaufort Sea to Baffin Bay.

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Above image illustrates that methane does show up prominently where the sea ice is thin, confirming earlier conclusions that the sea ice acts as a shield, a seal if you like, holding the methane in place and thus giving microbes the time needed to decompose the methane while it is held underneath the ice.

This spells bad news, because it implies that, as the sea ice thins, more methane will be able to enter the atmosphere and contribute to warming that is already accelerating in the Arctic.

As discussed in a recent post, methane is rising from the seafloor of the Arctic Ocean due to destabilization of sediments that hold huge amounts of methane in the form of free gas and hydrates. This destabilization is in part due to warm water flowing in the Arctic Ocean along the Gulf Stream. Record warm water was present off the coast of North America in July 2013, and this warm water took some time to reach the Arctic Ocean, as shown on the image below, from that earlier post.

Water in the currents that are returning water to the Atlantic Ocean north of Canada is typically cold, as indicated by the blue color on the image below. So, while it is possible that the water was still sufficiently warm to cause methane releases from the seabed in the Beafort Sea and in Baffin Bay, in the northern parts of Canada, it seems more likely that the methane originated from areas along the fault line that crosses the Arctic Ocean and that the methane traveled - underneath the sea ice - with these currents all the way to the edges of the sea ice where the ice is sufficiently fractured and thin to allow methane to rise to the surface.

Image credit: Jack Cook, Woods Hole Oceanographic Institute

This seems confirmed by recent sea surface temperature data, as pictured below.

As above image shows, sea surface temperature anomalies (in orange, red and brown) are still showing up prominently along many parts of the Gulf Stream, all the way into the Arctic Ocean, where anomalies of more than 8 degrees Celcius have been recorded for some time now. At the same time, colder water (in green and blue) is flowing back into the Atlantic Ocean from the Arctic Ocean, along the edges of Greenland and further south. Colder currents typically flow at greater depth, but the above image also shows colder waters emerging at sea surface level, especially in areas somewhat off the coasts of Newfoundland and Nova Scotia, effectively preventing some warm water from traveling along the Gulf Stream to the Arctic Ocean.

Why are the currents that are flowing out of the Arctic Ocean into the Atlantic Ocean so strong at the moment? Powerful winds have speeded up these currents, as illustrated by the 30-days Naval Research Laboratory animation below, which also includes a 7-days forecast from November 15, 2013.

One of the feedbacks of accelerated warming in the Arctic is stronger winds and a huge amount of sea ice is currently flowing into the Atlantic Ocean, partly due to these strong winds. Similarly, the Naval Research Laboratory animation below shows huge amounts of sea ice, often very thick ice, being pushed into the Atlantic Ocean.

Last but not least, the youtube video below, Arctic Death Spiral and the Methane Time Bomb, shows some of the most powerful video footage on climate change, highlighting the danger that methane will continue to rise from the seafloor of the Arctic Ocean in ever greater quantities, resulting in a wipe-out of civilization, extinctions at massive scale and devastation of the planet as we know it.

Post by Sam Carana.

Thursday, November 14, 2013

Horrific amounts of methane over Laptev Sea

For some time now, very high methane readings have been showing up over the Laptev Sea. Harold Hensel recently posted the image below with the huge areas solidly colored red indicating release of horrific amounts of methane. Harold adds the following comment:

"I am fighting for the lives of my children, grandchildren, and great grandchildren who's lifespan will extend 30 to 40 years from now. I am also fighting for all children of the world, animals, whales, dolphins, flowers and all living things. They are all in peril and we are the ones that may have a chance of doing something about it now. The threat of what is coming must sink in."

[ click on image to enlarge ]

The image below shows methane readings over a one-month period. As the image illustrates, high methane emissions, i.e. at 1850 ppb and higher, are more prevalent on the northern hemisphere, while emissions on the southern hemisphere are mostly under 1850 ppb. The contours of North America are visible, with Greenland to the north. Further north, over the Arctic Ocean, the color red dominates, indicating emissions of 1950 ppb and higher.

In which part of the Arctic Ocean are most emissions recorded? The image below shows recent methane readings of 1950 and higher, this time colored in yellow, for a period of just over one day during November 12 and 13, 2013. The largest area colored solid yellow is over the Laptev Sea, just north of Siberia.

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Below is an image of the same period as above image, but once more showing methane levels in ranges, i.e. readings of 1950 ppb and higher in red, as well as lower readings in orange and yellow. Over the Arctic Ocean, high methane readings dominate the picture, both readings of 1950 ppb and higher, and readings in the range of 1850 ppb to 1950 ppb.

[ click on image to enlarge ]

What makes high methane releases over the Laptev Sea so scary?

Vast amounts of methane are held in sediments under the Arctic Ocean. The Laptev Sea is part of the Eastern Siberian Arctic Shelf (ESAS, the rectangle on the image on the right). Shakhova et al. (2010) estimate the accumulated methane potential for the ESAS alone as follows:

organic carbon in permafrost of about 500 Gt
about 1000 Gt in hydrate deposits
about 700 Gt in free gas beneath the gas hydrate stability zone.

Shakhova et al. in 2008 considered release of up to 50 Gt of predicted amount of hydrate storage as highly possible for abrupt release at any time.

By comparison, the total amount of methane currently in the atmosphere is about 5 Gt.

Post by Sam Carana.

Monday, November 11, 2013

Methane Levels going through the Roof

On November 9, 2013, methane readings well over 2600 ppb were recorded at multiple altitudes, as illustrated by the image below.

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On November 9, 2013, p.m., methane readings were recorded as high as 2662 parts per billion (ppb), at 586 millibars (mb) pressure, which corresponds with an altitude of 14384.6 feet or 4384.4 meters.

Where did these high levels occur? Methane levels were low on the southern hemisphere and, while there were some areas with high readings over North America and Asia, there were no areas as wide and bright yellow as over the Arctic Ocean (the color yellow indicating readings of 1950 ppb and higher on above map).

As discussed in a previous post, huge amounts of methane are now escaping from the seabed of the Arctic Ocean, penetrating the sea ice, and entering the atmosphere, in a process that appears to be accelerating, resulting in huge amounts of methane in the atmosphere over the Arctic Ocean.

The image below gives an idea of the height of this level, compared to historic levels, and how fast levels of methane (CH4) have been rising compared to levels of two other greenhouse gases, i.e. carbon dioxide (CO2) and nitrous oxide (N2O).

Recent peak levels of methane over the Arctic Ocean may well have been even higher, since NOAA didn't release any readings for November 5-7, 2013.

Meanhwile, sea ice extent has stopped growing, as illustrated by the NSIDC graph below.

Data from the Cryosphere Today show that the area covered by sea ice has actually fallen over the past few days, as illustrated by the image below.

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There are several reasons why sea ice isn't growing, including high temperature anomalies in the Arctic, as illustrated by the NOAA image below, showing surface temperature anomalies of over 20 degrees Celsius on November 7, 2013.

High methane levels are contributing to temperature anomalies, by trapping additional sunlight in the atmosphere over the Arctic Ocean.

Furthermore, strong winds have hit the sea ice, as the recent post Methane, Faults and Sea Ice warned. Strong winds are pushing sea ice inward in the Kara Sea and in the Chukchi Sea, while pushing sea ice - up to 5 meters thick - out of the Arctic Ocean along the coast of Greenland, as illustrated by the Naval Research Laboratory animation below.

The Naval Research Laboratory image below shows ice speed and drift on November 9, 2013.

So, could Arctic sea ice collapse and totally disappear in September 2014? Posts at this blog have repeatedly warned about this, e.g. in this post. The image below, created by Wipneus, shows an exponential trendline pointing at zero volume sea ice in September 2016.

All data over the past two decades have fallen within the 95% confidence limits of an exponential trendline that points at imminent loss of all Arctic sea ice within years. September 2013 may have been "only" the 4th lowest on record, but such variability can be expected and may well cause sea ice to disappear completely as early as September 2014.

Strong winds can speed up such a collapse. On this point, it's good to remember what Prof. Peter Wadhams warned about in 2012:

". . apart from melting, strong winds can also influence sea ice extent, as happened in 2007 when much ice was driven across the Arctic Ocean by southerly winds (not northerly, as she stated). The fact that this occurred can only lead us to conclude that this could happen again. Natural variability offers no reason to rule out such a collapse, since natural variability works both ways, it could bring about such a collapse either earlier or later than models indicate.

In fact, the thinner the sea ice gets, the more likely an early collapse is to occur. It is accepted science that global warming will increase the intensity of extreme weather events, so more heavy winds and more intense storms can be expected to increasingly break up the remaining ice, both mechanically and by enhancing ocean heat transfer to the under-ice surface."

Guy McPherson lists 26 feedbacks that speed up warming, and many of these feedbacks occur in the Arctic, as described in the post Diagram of Doom.

Soon, calculates Prof. Peter Wadhams, the albedo loss due to decline of snow and ice in the Arctic will effectively more than double the net radiative forcing resulting from the emissions caused by all people of the world. Additional warming caused by methane releases from the Arctic seabed could be even more devastating.

Hopefully, more people will realize the urgency of the situation and realize the need for a comprehensive and effective plan of action as described here.

Saturday, November 9, 2013

Norwegian Sea hit by 4.6M Earthquake

In the early morning of November 9, 2013, the Norwegian Sea was hit by an earthquake with a magnitude of 4.6 on the Richter Scale. Earlier (on October 28, 2013), an earthquake with a 5.3 magnitude hit the Greenland Sea closer to Svalbard.

These earthquakes come at a time when huge amounts of methane are rising from the seabed of the Arctic Ocean, from areas on or close to the fault line that crosses the Arctic Ocean. The location of the earthquake that hit the Norwegian Sea is indicated on the map below with a white circle.