Methane concentrations in the Arctic are higher than elsewhere in the world, as shown on figure 1. below (
).
Methane is entering the atmosphere at high latitudes and spreading across the globe from there.
, pictured on figure 3. below, is warming up more than usual due to global warming. Specifically, pollution clouds pouring eastwards from the coast of Canada and the United States are the main culprit in heating up the Gulf Stream.
In July 2013, water off the coast of North America reached ‘Record Warmest’ temperatures and proceeded to travel along the Gulf Stream to the Arctic Ocean, where it is now warming up the seabed. Figure 4. below further shows that above-average temperatures were recorded in July 2013 along the entire path of the Gulf Stream into the Arctic Ocean.
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Figure 4. NOAA: part of the Atlantic Ocean off the coast of North America reached record warmest temperatures in July 2013 |
The mean speed of the Gulf Stream is 4 miles per hour (6.4 km/hour or 1.78 metres/second), but the water slows down as it travels north. In the much wider North Atlantic Current, which is its north eastern extension, the current flows 3.5 times slower (about 0.51 metres/second), while the
West Spitzbergen Current (WSC on figure 5. below) flows at about 0.35 metres/second (5 times slower).
The West Spitzbergen Current dives under the Arctic ice pack west of Svalbard, continuing as the Yermak Branch (YB on above map) into the Nansen Basin, while the Norwegian Current runs along the southern continental shelf of the Arctic Ocean, its hottest core zone at 300 metres depth destabilizing the methane hydrates en route to where the Eurasian Basin meets the Laptev Sea, a region of extreme methane hydrate destabilization and methane emissions. Figure 6. below, from an
earlier post by Malcolm Light, shows how warm water flows into the Arctic Ocean and warms up methane hydrates and free gas held in sediments under the Arctic Ocean.
Sediments underneath the Arctic Ocean hold vast amounts of methane. Just one part of the Arctic Ocean alone, the East Siberian Arctic Shelf (ESAS, see figure 7. below), holds up to 1700 Gt of methane. A sudden release of just 3% of this amount could add over 50 Gt of methane to the atmosphere, and experts consider such an amount to be
ready for release at any time.
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Figure 7. |
As above figure 7. shows, the total methane burden in the atmosphere now is 5 Gt. The 3 Gt that has been added since the 1750s accounts for
almost half of all global warming. The amount of carbon stored in hydrates globally was in 1992 estimated to be 10,000 Gt (
USGS), while a more recent estimate gives a figure of 63,400 Gt (
Klauda & Sandler, 2005). The ESAS alone holds up to 1700 Gt of methane in the form of methane hydrates and free gas contained in sediments, of which 50 Gt is ready for abrupt release at any time, and
Whiteman et al. calculate that an extra 50 Gt of methane would cause $60 trillion in damage. By comparison, the size of the world economy in 2012 was about $70 trillion.
Smaller releases of methane in the Arctic come with the same risk; their huge local warming impact threatens to further destabilize sediments under the Arctic Ocean and
trigger further methane releases, as illustrated by figure 8. below.
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Figure 8. |
Figure 9. below, from an
earlier post by Malcolm Light, shows that, besides the shallow methane hydrate regions in the ESAS, the Arctic Ocean slope and deep water regions contain giant volumes of methane hydrate deposits (methane frozen within the ice).
If only a few percent of this methane hydrate becomes destabilized, it will release enough methane into the atmosphere to cause a Permian Age-type massive extinction event. Recent methane emission maps show that, besides the emissions from the ESAS, huge amounts of methane are being released from other parts of the Arctic Ocean.
We now know that the subsea methane hydrate is destabilizing at a fast-increasing pace and the pattern of destabilization indicates that it is mainly caused by the increasingly hot “Gulf Stream” waters entering the Arctic west of Svalbard and through the Barents Sea. These “Gulf Stream” waters do a complete circuit in the Arctic, even under a complete floating ice cover, and will destabilize the methane hydrates they come in contact with before making an exit along the edges of Greenland. Methane is now also emerging from the waters of the Greenland coastline, where the southward-bound “Gulf Stream” waters exit the Arctic Ocean along the edges of Greenland.
Historically, methane has caused delayed temperature anomalies of some 20
°C, according to ice core analysis data, i.e. much higher than anomalies caused by carbon dioxide. Methane has a very high warming potential compared to carbon dioxide. Over a decade, methane’s global warming potential is more than 100 times as much as carbon dioxide, while methane’s local warming potential can be more than 1000 times as much. As a result, giant zones of circulating warm air in the Arctic have temperature anomalies in excess of 20
°C.
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Figure 10. [ click on image to enlarge ] |
These hot clouds, resulting from many feedbacks including this Arctic atmospheric methane build-up, show that methane’s delayed temperature anomaly of 20
°C has already caught up in the Arctic and is going to progressively spread around the world resulting in runaway global warming.
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Figure 11. [ click on image to enlarge ] |
Above figure 11. (by Sam Carana) and figure 12. below (by Malcolm Light) indicate that the critical mean atmospheric temperature anomaly of 8
°C will be reached between 2035 and 2050. At this temperature we can expect total deglaciation and extinction, according IPCC AR4 (2007).
By 2012, the mean atmospheric temperature had increased by some 0.8
°C by human induced global warming. This year however Australia has seen an anomalous 0.22
°C temperature increase. The new Australian temperature gradient implies that in ten years the atmosphere will be 2.2
°C hotter and in 30 to 40 years, 6.6 to 8.8
°C hotter which is consistent with the Arctic methane emission temperature increase curves of Carana and Light.
The reason for this sudden temperature increase in Australia this year is due to the fast building pall of methane in the Northern Hemisphere caused by global warming and destabilization of the subsea Arctic methane hydrates and the Arctic surface methane hydrate permafrosts.
At the moment, the entire Arctic is covered by a widespread methane cloud, but it is very concentrated (> 1950 ppb) over the Eurasian Basin and Laptev Sea where the subsea methane hydrates are being destabilized at increasing rates by heated Atlantic (Gulf Stream) waters. The area of the Eurasian Basin is similar to that of the East Siberian Arctic Shelf (ESAS) where Shakova et al. (1999) have shown that some 50 billion tons of methane could be released at any moment during the next 50 years from destabilization of subsea ESAS methane hydrates.
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Figure 13. Methane over the Arctic Ocean on December 3, 2013 [ click on image to enlarge ] |
At the moment, water saturated with methane is traveling underneath the ice carried by exit currents and emerging at locations where the sea ice is still less than one meter thick, such as in Baffin Bay and in Hudson Bay, as also shown on the animation below.
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[ this animation is a 1.5MB file and may take some time to fully load ] |
This massive volume of methane entering the atmosphere will produce catastrophic consequences for the global climate system. Furthermore global warming is now destabilizing methane hydrates in the Eurasian Basin even more than on the ESAS. The release of an additional 50 billion tons of methane or more from the Eurasian Basin over the next 50 years will further compound the catastrophe represented by the destabilization of methane hydrates on the ESAS. Essentially we have passed the methane hydrate tipping point and are now accelerating into extinction as the methane hydrate “Clathrate Gun” has begun firing increasingly large volleys of methane into the Arctic atmosphere.
The growth of the mean atmospheric temperature using the curves on figure 12 indicate that the mean atmospheric temperature anomaly will exceed 1.5
°C in 15 years and 2
°C in 20 years, at which time storm systems will be very extreme with droughts, flooding, sea level rise and the loss of Pacific islands. When the mean atmospheric temperature anomaly reaches 8
°C some 39 years in the future, there will be total deglaciation and a major extinction event that will culminate in a Permian-type extinction of all life on Earth.
If we do not stop the massive increases of Arctic methane emissions into the atmosphere the oceans will begin to boil off by 2080, when the mean temperature anomaly exceeds 115 to 120
°C and the temperatures will be like those on Venus by 2100 (see figure 12).
The present end of the financial crisis and recovery of the U.S. economy will take us down the same fossil fuel driven road to catastrophe that the U.S. has followed before, when they refused to sign the original Kyoto Protocols. Unless the United States and Canada reduce their extreme carbon footprints (per unit population), they will end up being found guilty of ecocide and genocide, as the number of countries destroyed by the catastrophic weather systems continues to increase.
The United States and Canada seek to expand their economies by increasingly frenetic extraction of fossil fuels, using the most environmentally destructive methods possible (fracking and shale oil), while the population’s total addiction to inefficient gas transport is leading our planet into suicide. We are like maniacal lemmings leaping to their deaths over a global warming cliff. What a final and futile legacy it will be for the leader of the free world to be remembered only in the log of some passing alien ship recording the loss of the Earth’s atmosphere and hydrosphere after 2080 due to human greed and absolute energy ineptitude.
The U.S. Government and Canada must ban all environmentally destructive methods of fossil fuel extraction such as fracking, extracting shale oil and coal and widespread construction of the now found to be faulty hydrocarbon pipeline systems. All Federal Government subsidies to fossil fuel corporations, for fossil fuel discovery and extraction must be immediately eliminated and the money spent solely on renewable energy development, which will provide many jobs to the unemployed. All long and short range (high consumption) fossil fuel-powered transport must be electrified or converted to hydrogen and where the range is too large, electric vehicles (including electric trains and ships) must be used instead of fossil fuel-powered trucks or aviation means of transport. All the major work for this conversion (including railway construction) can provide a new and growing set of jobs for the unemployed. Nuclear power stations must continue to be used and should be converted to the safe thorium energy system until the transition is complete.
The U.S. has to put itself on a war footing, but rather than fighting other military forces, it should recall its military forces from various places across the world and set them to work on the massive shift to renewable energy that the country needs to undertake if it wishes to survive the fast approaching catastrophe. The threat now comes from Mother Nature, who has infinite power at her disposal and intends to take no prisoners when she will strike back hard over a very short, absolutely brutal, 30-to-40-year period which has already begun. I cannot emphasise more, how serious humanity’s predicament is and what we should try to do to prevent our certain final destruction and extinction in 30 to 40 years if we continue down the present path we are following.
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Figure 14. |
Above action plan (figure 14.) includes efforts to move to a sustainable economy (part 1.) and efforts to reflect and divert heat away from the Arctic (part 2.). Furthermore, it includes action on methane escaping from hydrates in the Arctic (part 3.), as described at the
Arctic methane management page. Two types of methane management are further discussed below.
Arctic Methane Permanent Storage
In the
ANGELS Proposal, subsea Arctic methane is extracted, stored and sold as LNG for distribution as fuel, to produce fertilizer, etc. Permanent storage underground, however, is more preferable.
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Figure 15. |
As described by Sam Carana in an
earlier post, Prof. Kenneth Yanda, at the University of California, Irvine, has shown that methane can be stored in propane - methane hydrates that are stable at temperatures of ca 15
°C and low pressure (25 pounds per square inch - 1.66 atmospheres), very close to the ambient temperature and pressure conditions.
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Figure 16. |
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Figure 17. Methane capture in zeolite SBN. Blue represents adsorption sites, which are optimal for methane (CH4) uptake. Each site is connected to three other sites (yellow arrow) at optimal interaction distance. Credit: LLNL News |
Hydrates can be produced that contain larger cages for other gases and smaller cages for methane.
Methane can be converted into propane and other gases with UV light and the final goal would be long-term storage of these gases in the form of hydrates in deep waters such as those north of Alaska, suggests Sam Carana, adding that carbon dioxide can also then be sequestered in the hydrates, after its removal from the atmosphere.
Unlike carbon dioxide, methane is completely non-polar and reacts very weakly with most materials.
Three zeolite types (SBN, ZON and FER) have been found to
absorb methane at high to moderate rates (Figure 17, from Lawrence Livermore National Laboratory (LLNL) and UC Berkley, 2013).
These materials can help limit escape of fugutive gases from extraction, transport and distribution of methane.
Lucy and Alamo ProjectsThe
Lucy project seeks to decompose methane in the atmosphere.
In a new modified version of the Lucy Project, hydroxyls can also be generated by a polarized 13.56 MHZ beam intersecting the sea surface over the region where a massive methane torch (plume) is entering the atmosphere, so that the additional hydroxyl will react with the rising methane breaking a large part of it down. The polarized 13.56 MHZ radio waves will decompose atmospheric humidity, mist, fog, ocean spray, and the surface of the waves themselves in the Arctic Ocean into nascent hydrogen and hydroxyl (figure 18).
The newly determined atmospheric temperature gradient indicates that the mean global atmospheric temperature will reach 1.5
°C in 15 years and 2
°C in 20 years (Figure 14). Consequently we only have 15 years to get an efficient methane destruction radio - laser system designed, tested and installed (Lucy and Alamo (HAARP) Projects, figure 18) before the accelerating methane eruptions take us into uncontrollable runaway global warming. This will give a leeway of 5 years before the critical 2
°C temperature anomaly will have been exceeded and we will be looking at catastrophic storm systems, a fast rate of sea level rise and coastal zone flooding with its extremely deleterious effects on world populations and global stability.
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Figure 18. |