Showing posts with label Siberia. Show all posts
Showing posts with label Siberia. Show all posts

Sunday, August 14, 2016

Wildfires in Russia's Far East

Wildfires can add huge amounts of carbon dioxide (CO2), carbon monoxide (CO), methane (CH4), nitrous oxide (N2O) and black carbon (BC or soot) into the atmosphere.

While CO and soot are not included as greenhouse gases by the IPCC, they can have strong warming impact. CO acts as a scavanger of hydroxyl, thus extending the lifetime of methane. BC results from biomass burning, which a study by Mark Jacobson found to cause 20 year global warming of ~0.4 K. Moreover, BC has a darkening effect when settling on snow and ice, making that less sunlight gets reflected back into space, which accelerates warming. This hits the Arctic particularly hard during the Northern Summer, given the high insolation at high latitudes at that time of year.

The image below shows fires around the globe on August 12, 2016.


Visible in the top right corner of above image are wildfires in Russia's Far East. The image below zooms in on these wildfires.


The image below shows carbon dioxide levels as high as 713 ppm and carbon monoxide levels as high as 32,757 ppb on August 12, 2016, at the location marked by the green circle, i.e. the location of the wildfires in Russia's Far East.


As said, wildfires can also emit huge amounts of methane. The image below shows methane levels as high as 2230 ppb at 766 mb.


The magenta-colored areas on above image and the image below indicate that these high methane levels are caused by these wildfires in Russia's Far East. The image below shows methane levels as high as 2517 ppb at 586 mb.


Methane levels as high as 2533 ppb were recorded that day (at 469 mb), compared to a mean global peak of 1857 ppb that day.

Analysis by Global Fire Data found that the 2015 Indonesian fires produced more CO2e (i.e. CO2 equivalent of, in this case, CO2, CH4 and N2O) than the 2013 CO2 emissions from fossil fuel by nations such as Japan and Germany. On 26 days in August and September 2015, emissions from Indonesian fires exceeded the average daily emissions from all U.S. economic activity, as shown by the WRI image below.

A recent study calculated that Indonesia’s 2015 fires killed 100,000 people.

Methane emissions from wildfires can sometimes be broken down relatively quickly, especially in the tropics, due to the high levels of hydroxyl in the atmosphere there. Conversily, methane from wildfires at higher latitudes can persist much longer and will have strong warming impact, especially at higher latitudes.

Similarly, CO2 emissions from wildfires in the tropics can sometimes be partly compensated for by regrowth of vegetation after the fires. However, regrowth can be minimal in times of drought, when forests are burned to make way for other land uses or when peat is burned, and especially at higher latitudes where the growth season is short and weather conditions can be harsh. Carbon in peat lands was built up over thousands of years and even years of regrowth cannot compensate for this loss.

A recent study concludes that there is strong correlation between fire risk for South America and high sea surface temperatures in the Pacific Ocean and the Atlantic Ocean. This makes the current situation very threatening. As the image below shows, sea surface temperature anomalies were very high on August 12, 2016.

Sea surface temperature and anomaly. Anomalies from +1 to +2 degrees C are red, above that they turn yellow and white
Above image also shows that on August 12, 2016, sea surface temperatures near Svalbard (at the location marked by the green circle) were as high as 18.9°C or 65.9°F, an anomaly of 13.6°C or 24.4°F. These high temperatures threaten to melt away the Arctic's snow and ice cover, resulting in albedo changes that accelerate warming, particularly in the Arctic. Warming of the Arctic Ocean further comes with the danger that methane hydrates at its seafloor will destabilize and make that huge amounts of methane will enter the atmosphere.

The situation is dire and calls for comprehensive and effective action, as described in the Climate Plan.


Links

 Effects of biomass burning on climate, accounting for heat and moisture fluxes, black and brown carbon, and cloud absorption effects, by Mark Z. Jacobson (2014)
http://onlinelibrary.wiley.com/doi/10.1002/2014JD021861/abstract

 2016 fire risk for South America
http://www.ess.uci.edu/~amazonfirerisk/ForecastWeb/SAMFSS2016.html

 Global Fire Data - 2015 Indonesian fires
http://www.globalfiredata.org/updates.html#2015_indonesia

 Indonesia’s Fire Outbreaks Producing More Daily Emissions than Entire US Economy (2015)
http://www.wri.org/blog/2015/10/indonesia%E2%80%99s-fire-outbreaks-producing-more-daily-emissions-entire-us-economy

 Indonesia’s 2015 fires killed 100,000 people, study finds
http://www.climatechangenews.com/2016/09/19/indonesias-2015-fires-killed-100000-people-study-finds

 Smoke from 2015 Indonesian fires may have caused 100,000 premature deaths
https://www.seas.harvard.edu/news/2016/09/smoke-from-2015-indonesian-fires-may-have-caused-100000-premature-deaths

 High Temperatures in the Arctic
http://arctic-news.blogspot.com/2015/06/high-temperatures-in-the-arctic.html


Thursday, July 2, 2015

East Siberian Heat Wave

The image below illustrates the intensity of the heatwave over western Europe, with temperatures forecast to keep hitting the top end of the scale for days to come.


Global warming is strengthening heatwaves. The Arctic is warming faster than the rest of the world, so the temperature difference between the North Pole and the Equator is getting smaller. It is this temperature difference that powers the jet stream. The result is that the speed at which the jet stream circumnavigates the globe is falling. Furthermore, the path of the jet stream is changing, sometimes extending far to the north, then deeper to the south, just like a river will meander more where the land is flatter.


Above image illustrates that these changes to the jet stream make that warm air from the south can more easily move up north, to higher latitudes, while cold air from the Arctic can more easily move down to lower latitudes, in both cases further decreasing the temperature difference between the North Pole and the Equator, which makes these changes to the jet stream a self-reinforcing feedback loop that is rapidly making the situation worse.

While such developments have been documented for years, e.g. see this feedbacks page, the media rarely inform people about them. And while the media do cover the suffering caused by the heatwaves that have been hitting populous countries such as India, Pakistan, the U.S., Spain and France recently, less attention is given to heatwaves hitting the Arctic.

High temperatures close to the Arctic Ocean are very worrying, for a number of reasons, including:
  • They are examples of heatwaves that can increasingly extend far to the north, all the way into the Arctic Ocean, speeding up warming of the Arctic Ocean seabed and threatening to unleash huge methane eruptions. 
  • They set the scene for wildfires that emit not only greenhouse gases such as carbon dioxide and methane, but also pollutants such as carbon monoxide (that depletes hydroxyl that could otherwise break down methane) and black carbon (that when settling on ice causes it to absorb more sunlight). 
  • They cause warming of the water of rivers that end up in the Arctic Ocean, thus resulting in additional sea ice decline and warming of the Arctic Ocean seabed.
June 24, 2015 - Smoke from wildfires in Alaska - from: wunderground.com

The video below was created by Stuart Thrupp from a NASA animation showing carbon monoxide from Alaska wildfires spreading over the Arctic from June 17th to 29th, 2015.


Short movie of carbon-monoxide levels over Alaska. June 17th- June 29th. Thanks for NASA Eyes on earth for there animation.
Posted by Stuart Thrupp on Wednesday, July 1, 2015
The heatwaves that hit Alaska and Russia recently are now followed up by a heatwave in East Siberia.

The image below shows a location well inside the Arctic Circle where temperatures as high as 37.1°C (98.78°F) were recorded on July 2, 2015. The top panel shows temperatures, while the bottom panel also shows the depth of the Arctic Ocean and the location of the Gakkel Ridge, in between the northern tip of Greenland and the Laptev Sea.


As the image below shows, the jet stream is forecast to move up high into the Arctic north of Siberia over the next few days. The image shows the jet stream as at July 8, 2015.


The image below shows a forecast of temperature anomalies for July 7, 2015.


The four images below illustrate how the heatwave is forecast to develop over the next few days (hat tip to Mark Richardson).


Rain close to the North Pole (forecast July 7, 2015)
The image on the right, also created with a Climate Reanalyzer image, shows rain over the Arctic, over the East Siberian Sea and over an area close to the North Pole.

Rain over sea ice will create melt ponds with associated loss in albedo (reflectivity), making that light that was previously reflected back into space by the sea ice will instead be absorbed by the water, further speeding up the demise of the sea ice.

The picture below was taken July 2, 2015, by WebCam#1, mounted on a satellite-reporting buoy. The camera provides a wide-angle 120° horizontal field of view and was installed in April 2015, about 1.5 m above the ice surface, at a location some 25 miles from the North Pole. The buoy has meanwhile drifted some distance away from the North Pole, see map at this page.

WebCam#1 showing water on July 2, 2015
The presence of water can indicate that the sea ice has completely disappeared in the respective area, which could in turn be caused by sea ice melting and/or bubbling up of methane, so it's important to keep monitoring this. More likely though, the water is probably surface water on top of the ice, caused by melting and/or rain. Anyway, water reflects less sunlight back into space than sea ice, so the result will be that more sunlight is instead absorbed by the water and/or the sea ice.

With temperatures as high as the 37.1°C (98.78°F) recorded on July 2, 2016 (image further above), huge melting can be expected where there still is sea ice in the waters off the coast of Siberia, while the waters where the sea ice has already gone will warm up rapidly.

Note that the waters off the coast of Siberia are less than 50 m (164 ft) deep, so warming can quickly extend all the way down to the seabed, that can contain enormous amounts of methane in the form of free gas and hydrates.

The situation is dire and calls for comprehensive and effective action, as discussed at the Climate Plan.



While the media gives wide coverage to the heatwaves that have been hitting populous countries such as India, Pakistan,...
Posted by Sam Carana on Thursday, July 2, 2015

Friday, April 10, 2015

North Siberian Arctic Permafrost Methane Eruption Vents

Mantle Methane Leakage via Late Permian Deep Penetrating Fault and Shear Fracture Systems Rejuvenated by Carbon Dioxide and Methane Induced Global Warming

By Malcolm P.R. Light, Harold H. Hensel and Sam Carana

Abstract

In North Siberia some 30 permafrost methane eruption vents occur along the trend of the inner (continental side) third of the Late Permian Taimyr Volcanic Arc where the crust and mantle were the weakest and the most fractured. Deep penetrating faults and shear systems allowed molten basaltic magmas charged with large volumes of carbon dioxide and methane free access to the surface where they formed giant pyroclastic eruptions. The large volume of carbon dioxide and methane added to the atmosphere by this Late Permian volcanic activity led to a massive atmospheric temperature pulse that caused a major worldwide extinction event (Wignall, 2009). These deep penetrating fractures form a major migration conduit system for the presently erupting methane vents in the North Siberian permafrost and the submarine Enrico PV Anomaly. During periods of lower atmospheric carbon dioxide and lower temperatures, the permafrost methane vents became sealed by the formation of methane hydrate (clathrate) plugs forming pingos. The surface methane clathrate plugs are now being destabilized by human pollution induced global warming and the mantle methane released into the atmosphere at the permafrost methane explosion vents. This has opened a giant, long standing (Permian to Recent) geopressured, mantle methane pressure-release safety valve. There is now no fast way to reseal this system because it will require extremely quick cooling of the atmosphere and the Arctic Ocean. The situation calls for comprehensive and effective action, including breaking down the methane in the water before it gets into the atmosphere using methane devouring symbiotic bacteria (Glass et al. 2013) and simultaneously breaking down the existing atmospheric methane using radio-laser systems which can also form methane consuming hydroxyl molecules (Alamo and Lucy Projects, Light and Carana, 2012, 2013).


Permafrost Methane Eruption Vents

During 2014 and 2015 at least 30 methane eruption vents, 7 of which are very large were identified in northern Siberia in the permafrost (Figures 1 to 3)(Zulinova in Liesowska 2015, Wales, 2015, Wignall 2009, Light 2014, Scribbler R., 2015). Of the seven major methane eruption vents (craters) in the Arctic area, 5 are on the Yamal Peninsula, one is in the Yamal Autonomous District and the seventh near Krasnoyarsk close to the Taimyr Peninsula (Figure 3, Liesowska, 2015). This permafrost methane eruption vent zone correlates with the inner third of the continental side of the Late Permian Age Taimyr Volcanic Arc where the top of the underlying Permian subduction zone lay at a depth between 200 km and 225 km (Figure 3, Light 2014). These methane eruption vents occur along fracture systems, transform faults, strike slip-slip faults oblique to the subduction direction and normal fault lines that also cut the Permian volcanic arc and the permafrost up to the continental edge of the arc (Figure 3).


Late Permian Extinction Event

In the Late Permian a massive eruption phase occured along the entire central and north eastern part of the "Taimyr Volcanic Arc" producing an extremely wide and thick sheet-like succession of flood trap lavas and tuffs (Siberian Traps Large Igneous Province) that spread south eastwards over the Siberian Craton (Figure 2, Light 2014). During the Late Permian there was a major global extinction event which resulted in a large loss of species caused by catastrophic methane eruptions from destabilization of subsea methane hydrates in the Paleo-Arctic (Figures 2, 3 and 4)(Wignall 2009, Light 2014, Scribbler 2015, Merali 2004, Goho 2004, Scott et al, PNAS, Dawson 1967, Kennedy and Kennedy, 1976). Extreme global warming was caused when vast volumes of carbon dioxide were released into the atmosphere from the widespread eruption of volcanics in northern Siberia (Figure 2; Wignall 2009) whose main source zone, the "Taimyr Volcanic Arc" on land in northern Siberia (Figure 3) is not a great distance from the present trend of the Arctic Ocean Gakkel Ridge and the Enrico Pv Anomaly extreme methane emission zone. Because the Arctic forms a graveyard for subducted plates, the mantle there is highly fractured and it is also a primary source zone for mantle methane formed from the reduction of oceanic carbonates by water in the presence of iron (II) oxides buried to depths of 100 km to 300 km in the Asthenosphere and at temperatures above 1200°C (Figure 4)(Gaina et al. 2013; Goho 2004; Merali 2004; Light 2014).

In addition to the widespread eruption of volcanics in Northern Siberia in the Late Permian (250 million years ago), swarms of pyroclastic kimberlites also erupted between 245 and 228 million years ago along a NNE trending shear system in the mantle which extends up the east flank of the Lena River delta and intersects the Gakkel Ridge slow spreading ridge on the East Siberian Arctic Shelf (Figure 4). Cenozoic volcanics also occur to the north and north east of the Lena River delta marking the trend of the slow spreading Gakkel Ridge on the East Siberian Arctic Shelf (Sekretov 1998). All this pyroclastic activity along the slow spreading Gakkel Ridge from the Late Permian to the present is evidence of deep pervasive vertical mantle fracturing and shearing which has formed conduits for the release of carbon dioxide and deeply sourced mantle methane out of Siberia and the Arctic sea floor into the atmosphere (Light 2014).

Thermodynamic Conditions Necessary to form Mantle Methane

On a vertical temperature - pressure/ depth cross section (Figure 4) the surface methane eruption vents are fed from vertical crustal and mantle fractures from more deeply sourced mantle methane below 225 km depth that has migrated up the fractured and sheared surface of the Late Permian subducting oceanic plate and then entered the vertical fractures allowing it to the surface where the methane is now erupting along the inner (continental side) third of the "Taimyr Volcanic Arc" (Dawson, 1967, Kennedy and Kennedy 1976. Merali 2004, Goho 2004, Scott et al, PNAS, Light 2014). What is remarkable is that the present surface methane eruption vent region corresponds exactly to the zone where the crust and mantle was the weakest in the Late Permian because the continental rock melt line (dry solidus) rises steeply to within a few km of the surface peaking exactly in the centre of zone defined by the methane eruption vents (Figure 4).

This implies that in the Late Permian, the inner continental side of the volcanic arc was a region of intense pyroclastic volcanic activity because the lavas were highly charged in carbon dioxide and methane. The eruption of these gases led to massive peak in global warming that culminated in the Major Late Permian Extinction Event when mean global atmospheric temperatures exceeded 26.6°C (Wignall. 2009).

This inner (continental side) third of the "Taimyr Volcanic Arc" was thus severly fractured by extreme pyroclastic volcanic activity and gas effusions in the Late Permian and has remained so up to the present day thus forming a major migration conduit system for the presently erupting methane vents in the Siberian permafrost. During periods of lower atmospheric carbon dioxide and lower temperatures the permafrost methane vents became sealed by the formation of methane hydrate (clathrate) plugs forming pingos (Figures 5, 6 and 7; Hovland et al. 2006; Paull et al., 2007; Carana, 2011, Liesowska, 2015). The surface methane clathrate plugs have now been destabilized by human pollution induced global warming and the methane is being released into the atmosphere at the permafrost methane explosion vents. Extreme methane concentrations, up to 1000 times above the mean atmospheric level has been found at the base of the methane eruption vents by Russian scientists (Holthaus, 2015) confirming that they are still linked to deeper methane sources which may be geopressujred. Before the Yamal B1 methane eruption vent developed, hillocks (pingoes) rose in the permafrost heralding the coming massive methane gas eruption (Figure 7; Liesowska, 2015). Other pingoes adjacent to the Yamal B1 methane eruption vent could also collapse at any moment emitting a large cloud of methane gas (Liesowska, 2015).
In the Last Ice age, the methane seal system (methane hydrate pingos) was maintained by the low temperatures and trapped the mantle methane below the ground. Now however human pollution which caused a massive carbon dioxide atmospheric buildup exceeding 400 ppm has started to break the seals on the mantle methane fractures in 2014 and 2015 allowing them to spew increasingly large quantities of deep mantle methane directly into the Arctic atmosphere. In the Late Permian, the massive volume of carbon dioxide released into the atmosphere during these cataclysmic eruptions produced extreme global warming in the air and oceans which also dissasocciated the Paleo-Arctic permafrost and subsea methane hydrates and the methane hydrate seals above the Enrico Pv Anomaly generating a massive seafloor and mantle methane pulse into the atmosphere that caused the Major Late Permian Extinction Event (Figures 2 to 4) (Wignall. 2009).

A sequence of extreme pyroclastic basaltic eruptions occur along the Gakkel Ridge (85oE volcanoes) which has an ultra - slow rate of plate spreading of 15 to 20 mm a year (Sohn et al. 2007). These volcanoes formed from the explosive eruption of gas - rich basaltic magmatic foams as shown by recovered green - glass fragments and pillow lavas. Long intervals between eruptions during slow spreading produced a huge gas and volatile buildup at high storage pressures deep down in the crust (Sohn et al 2007). A volatile and carbon dioxide content of some 13.5% to 14% (Wt./Wt. - volume fraction 75%) is necessary at 5 km depth in the Arctic Ocean to fragment the erupting magma (Sohn et al. 2007). These extreme pyroclastic basaltic volcanic eruptions are probably a modern day equivalent of the types of eruptions that occured in the region of methane eruption vents along the "Taimyr Volcanic Arc" in the Late Permian and totally fractured the mantle and crust producing deep reaching conduits that allowed mantle methane below 225 km access to the surface (Figure 4). The more fluid Gakkel Ridge pillow lava basalts mirror the very fluid Siberian "Trapp" flows that covered a large part of Siberia in the Late Permian (Figure 2 and 3).

Conclusions

Our present extreme fossil fuel driven, carbon dioxide global warming is predicted to produce exactly the same mantle methane release from the permafrost methane eruption vents along the Late Permian "TaimyrVolcanic Arc", subsea Arctic methane hydrates and the Enrico Pv Anomaly "Extreme Methane Emission Zone" by the 2050's, leading to total deglaciation and the extinction of all life on Earth.

Mankind has, in his infinite stupidity, with his extreme hydrocarbon addiction and fossil fuel induced global warming, opened a giant, long standing (Permian to Recent), geopressured, mantle methane pressure-release safety valve for methane gas generated between 100 km and 300 km depth and at temperatures of above 1200°C in the asthenosphere (Figures 1 to 6). This is now a region of massive methane emissions (Carana, 2011-2015).

There seems to be no fast and easy way to reseal this system. To sufficiently cool the Atmosphere and Arctic Ocean cannot be achieved in the short time frame we have left to complete the job. In some cases, it may be possible to reseal conduits with concrete or other material, or to capture methane for storage in hydrates at safer locations, but the sheer number of vulnerable locations and the size of the work involved is daunting.

Figure 9. Climate Action Plan, from Climate Plan
Other ways to deal with the methane are to break it down in the water and in the atmosphere, as also depicted in Figure 9 (enhanced decomposition). Efforts to break down methane in the atmosphere using radio-laser systems have been described by Light and Carana (Figure 8, Alamo and Lucy Projects, Light and Carana, 2012, 2013, Ehret 2012; Sternowski 2012; Iopscience, 2013, Arctic-news, 2012). Scientists at Georgia Tech. University have found in the ocean that at very low temperatures two symbiotic methane eating organisms group together, consume methane in the presence of tungsten and excrete carbon dioxide which then reacts with minerals in the water to form carbonate mounds (Glass et al. 2013). This means that the United States must fund a major project at Georgia Tech. to quickly develop the means to grow these methane consuming bacteria in massive quantities with their tungsten enzyme and find the means to deliver them to the Polar oceans as soon as possible. More generally, the situation calls for comprehensive and effective action, as discussed at the Climate Plan blog.


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Figure References

Figure 7. Enhanced Lucy Transmission System. Image from Light and Carana 2012. Lidar methane detecting laser from Ehret, 2012. Methane heating laser from Sternowski, 2012. Hydroxyl formation from iopscience.iop.org, 2013.


North Siberian Arctic Permafrost Methane Eruption Vents | by Malcolm Light, Harold Hensel and Sam Caranahttp://arctic-news.blogspot.com/2015/04/north-siberian-arctic-permafrost-methane-eruption-vents.html

Posted by Sam Carana on Friday, April 10, 2015