CryoSat

The image below shows how much the older, thicker sea ice has declined over the years. This decline doesn't become apparent when focusing on sea ice extent; volume measurements are needed to reveal this decline.

Old versus new ice in Arctic: The maps show the median age of sea ice in March 1985 (left) and March 2011 (right).
Overall, the proportion of old ice has decreased. By March 2011, ice over 4 years old accounts for less than
10% of the Arctic ice cover. Credit: National Snow and Ice Data Center, University of Colorado, Boulder.

The screenshot below shows GHRSST volume measurements from National Centre for Ocean Forecasting website.

The European Space Agency's CryoSat promises to deliver an even clearer picture. One of the scientists analyzing the CryoSat data, Dr Seymour Laxon, said in April 2012 that CryoSat's volume estimate is very similar to that of PIOMAS, the model developed at the Polar Science Center at the University of Washington.

In a recent interview, Dr Laxon said that if the current trend continues, the Arctic could be ice-free at the height of summer by the end of the decade.

John Nissen, Chair of the Arctic Methane Emergency Group (AMEG), comments: "Dr Laxon failed to mention the data on sea ice thickness that has been collected over many years by sea ice expert Professor Peter Wadhams of the University of Cambridge, who now considers that the Arctic Ocean will be seasonally free of sea ice most probably by September 2016. PIOMAS sea ice volume data suggest that a collapse in sea ice area could occur even sooner, as discussed on the AMEG blog posting."

Huge cyclone batters Arctic sea ice

The image below shows an unusually large and powerful cyclone that was churning over the Arctic in early August 2012. Two smaller systems merged on August 5 to form the storm, which at the time occupied much of the Beaufort-Chukchi Sea and Canadian Basin, reports NASA Earth Observatory. On average, Arctic cyclones last about 40 hours; as of August 9, 2012, this storm had lasted more than five days.

This cyclone’s central sea level pressure reached about 964 millibars on August 6, 2012—a number that puts it within the lowest 3% of all minimum daily sea level pressures recorded north of 70 degrees latitude, noted Stephen Vavrus, an atmospheric scientist based at the University of Wisconsin.

Image by By NASA Goddard Photo and Video

NASA’s Aqua satellite captured above natural-color mosaic image on August 6, 2012. The center of the storm at that date was located in the middle of the Arctic Ocean.

The combined screenshots (6 & 8 August) below from Oceanweather Inc give an idea of size of the waves churned up by the cyclone.

The storm came in from Siberia, intensified and then positioned itself over the central Arctic, engendering 20 knot winds and 50 mph wind gusts, reports Skeptical Science.

The Arctic Sea Ice Blog covered the unfolding events well, in a series of posts including:

• Cyclone warning!
• Arctic storm part 1: in progress
• Arctic storm part 2: the color purple
• Arctic storm part 3: detachment
• Further detachment
• Arctic summer storm open thread 1

Many excellent comments were also added underneath these posts, e.g. by Steve Coulter who noted that "when fragmented floes are present, each irregular piece of ice acts as a sail in the wind, so the wind transfers momentum more readily to the surface. And each piece of ice, being 90% submerged, quite effectively transfers that momentum to the water. With winds moving in essentially a single direction in any given area, vast volumes of surface water are more readily put into motion. The difference in motion between the surface and deep water inevitably creates mixing."

Such mixing could mean that sediments that have been frozen until now get exposed to warmer water. This could destabilize methane contained in such sediments, either in the form of free gas or hydrates.

John Nissen, Chair of the Arctic Methane Emergency Group (AMEG), comments:

"There are at least three positive feedbacks working together to reinforce one another - and now a fourth on salinity:

1. The albedo flip effect as sea ice is replaced by open water absorbing more sunlight, warming and melting more sea ice.
2. As the sea ice gets very thin, it is liable to break up easily and get blown into open water where it will melt more easily.
3. The open warmer water is allowing increased strength of storms, which break up the ice to make for more open water.
4. The storms are churning up the sea to a depth of 500 metres, producing salinity at the surface that will mean slower ice formation in winter and more open water next year.

These feedbacks are dangerous for methane. AMEG has been warning that, as the sea ice retreats, storms will warm the sea bed, leading to further release of methane. In ESAS, we only need mixing to a depth of 50 metres - so a storm capable of mixing to 500 metres will really stir things up.

These feedbacks are also dangerous for food security, already damaged through climate extremes induced by Arctic warming, hence our piece in the Huffington Post.

The only way to head off catastrophe is to cool the Arctic, which must involve geoengineering as quickly as possible. We must try to remain positive and determined about this, despite the gloomy news."

Above image shows a retreat in sea ice area to 3.15521 million km² on the 221^st day of 2012, down from 3.91533 million km² on the 212^th day of 2012, from The Cryosphere Today.

The 30-days animation below, from the Naval Research Laboratory, show the recent ice speed and drift.

The 30-days animation below, also from the Naval Research Laboratory, show recent decline of the thickness of the sea ice.  

Supplementary evidence to the EAC from John Nissen on behalf of AMEG

Supplementary evidence to the Environmental Audit Committee (EAC) from John Nissen on behalf of AMEG

The Growing Crisis in the Arctic

I am writing on behalf of AMEG, the Arctic Methane Emergency Group, in regard to conflicting evidence you have received during your inquiry “Protecting the Arctic”.

The inquiry is both a highly commendable reaction to, and a highly authoritative confirmation of, the fact that for the last few decades the Arctic environment is being changed at a rate unprecedented in human history. The world’s scientific establishment is unequivocal that these changes to the Arctic environment, particularly the retreating sea ice, were initiated as a consequence of global greenhouse gas emissions arising from human activities. But, as the sea ice retreats, the open water absorbs more sunshine, warming the water and melting more ice in a vicious cycle known as “positive feedback”. Thus global warming from greenhouse gases is amplified in a process known as “Arctic amplification”. There is good evidence to suggest that the Arctic is currently warming several times faster than the average over the whole planet, see Appendix.

In the course of the EAC’s ongoing inquiry it has focused on the issue of the retreating sea ice because it is this feature of the changing environment that has attracted the interests of the oil, shipping and fishing industries and is also the critical disruptive element in the Arctic environment. AMEG representatives, Professor Peter Wadhams and I, have pointed out extreme dangers associated with the retreat, warranting the designation of a planetary emergency – a crisis of unprecedented magnitude to threaten all mankind – a matter of national and international security.

The EAC invited many organisations to give their evidence on how the near future of the Arctic would play out. AMEG provided compelling evidence that not only was the rate of reduction of sea ice extent and depth much higher than is currently being predicted by models (such as used by the Hadley Centre) but that the consequential release of entrapped methane, an extremely powerful greenhouse gas, was also accelerating, risking catastrophic exacerbation of global warming in coming decades. However the chain reaction of Arctic warming and further methane release could be stifled if the Arctic were cooled quickly by measures including geoengineering.

In her evidence, Professor Julia Slingo of the Meteorological Office flatly contradicted the AMEG evidence, particularly the evidence of rapid sea ice retreat given by Professor Wadhams. Especially, Professor Slingo said she did not find the PIOMAS volume data credible, and she was expecting to see “better data” fitting the Hadley Centre models soon. We wish to point out that it is quite extraordinary that Professor Wadhams, an acknowledged expert on sea ice who has spent many years studying sea ice thickness, should have his evidence thus repudiated. However, the committee might bear in mind that the reputation of the Hadley Centre, part of the Met Office, is largely based on their modelling expertise; and their models are still predicting the sea ice demise many decades in the future. Thus Professor Slingo was in effect attempting to defend the Hadley Centre reputation.

What the committee may not know is that there was a whole assemblage of models used by the IPCC in 2007 for their AR4 report. Most of these models predicted the sea ice survival beyond the end of the century. None of the models showed the positive feedback from sea ice retreat that we refer to above. An excuse could be made that this feedback is difficult to quantify and to model, so was omitted on procedural grounds. However the resultant predictions bore no relation to reality. Even in the 1990s, the observations of sea ice extent were deviating from the most pessimistic of the models. Then in September 2007 the sea ice extent plummeted to a record low, about 40% below the level at start of satellite measurement. Nevertheless, IPCC, supported by models from the Hadley Centre, continued on the assumption that global warming predictions could be made for the whole century without taking into account possible sea ice disappearance and massive methane release. Even with the “wake-up call” of sea ice retreat in 2007, the Hadley Centre would not admit that their models were fundamentally flawed and they continue to ignore the evidence of sea ice volume, which is showing an exponential downward trend.

Note that in their written evidence to EAC, the Met Office says: “In September 2007, sea ice extent reached an all-time low, raising the question of whether the sea ice is likely to melt more quickly than has been projected. There is, however, no evidence to support claims that this represents an exponential acceleration in the decline.” They also assure the EAC to trust models giving 2040 as the earliest date for the Arctic to become ice-free during summer. However the PIOMAS volume data clearly shows acceleration in decline, a close fit to the exponential trend curve, and a likely date for an ice-free September around 2015. (Note that as the volume approaches zero, so must the extent, implying a collapse in extent before 2015.)

And they are even now ignoring the evidence of the growing methane emissions from the East Siberian Arctic Shelf (ESAS) where “vast plumes of methane bubbles, many over a kilometre across” have been reported arising from the seabed by the Russian scientists, Shakhova and Semiletov. In her oral evidence, Professor Slingo shows apparent ignorance of the Arctic methane situation, which may have misled the committee. She ignores the vast area of ESAS (over 2 million square kilometres) and claims that only a small fraction of methane from hydrates reaches the surface. That may be true for methane from the shelf margins at several hundred meters depth; but the shelf itself is mostly less than 40 metres deep, so the methane has little time to be oxidised and most of it reaches the surface. Furthermore she suggests only a small rise in temperature at the seabed, but in ESAS temperature rises of up to 6 degrees have been recorded. Far from the stratification of the water, which Professor Slingo suggests, there has been a growing turbulence as the sea ice cover is removed, resulting in this seabed warming.

This denial of the true situation might mislead the committee into thinking that there is no significant amount of methane entering the atmosphere, let alone a growth. But methane detection stations show recent spikes in methane levels which can only be easily explained by seabed origin. Furthermore satellite measurements have shown a growing anomaly of excess methane over the Arctic Ocean, again suggesting a seabed origin. All this evidence was available to the Met Office but they chose to ignore it.

Thus the Met Office (and Hadley Centre within it) is party to a complete denial of what is actually happening in the Arctic with accelerated warming, precipitous decline in sea ice and ominous rise in methane emissions.

Margaret Thatcher, in her opening of the Hadley Centre, 25th May 1990 said: “Today, with the publication of the Report of the Inter-Governmental Panel on Climate Change, we have an authoritative early warning system… [This] Report confirms that greenhouse gases are increasing substantially as a result of Man's activities; that this will warm the Earth's surface, with serious consequences for us all, and that these consequences are capable of prediction. We want to predict them more accurately and that is why we are opening this Centre today.”

We wish to hold the Met Office and its chief scientist to account for putting out scientifically unfounded and incorrect information to delude the government and public that no possible Arctic planetary emergency exists.

The importance of the sea ice for the planet is not in dispute; it provides a reflective mirror to reflect solar energy back into space, thus cooling the planet. James Lovelock has made his own estimate that loss of sea ice would be equivalent to the warming of all the CO2 that has accumulated in the atmosphere as a result of mankind’s emissions over the past century. In any event, recent research has confirmed that retreat of sea ice to date is a major cause of Arctic amplification. Therefore, if the Arctic Ocean were to become free of sea ice for several months of the year, as possible by 2020 according to the PIOMAS data, there would necessarily be a spurt in Arctic warming. This would be serious in terms of mounting disruption of the Northern Hemisphere climate system (see below). But it would also lead to an inevitable increase in the rate of methane release, risking the onset of an unstoppable methane feedback, whereby the methane causes further Arctic warming and in turn further methane emission in a positive feedback loop. A warning of the danger to all humanity from such methane feedback has been made by top scientists, such as US Energy Secretary and Nobel Laureate, Steven Chu, and NASA climate scientist, Jim Hansen. The likelihood of runaway methane feedback as the sea ice disappears cannot be easily estimated from current evidence, but, even if small, it has to be considered seriously because of the extraordinary devastation were it to get going.

The current disruption of the Northern Hemisphere climate system, with an ever increasing incidence of severe heat waves on the one hand and severe flooding on the other, is likely due to the warming of the Arctic in relation to the tropics, thus reducing the temperature differential that has a stabilising effect on the jet stream and weather system patterns. There is evidence that the jet stream is now getting “stuck” such as to cause the unusual and unpredictable weather which is of considerable concern to farmers. Allowing the Arctic to continue warming is thus a very real danger to food security – which is a strong argument for cooling the Arctic, regardless of other considerations.

The evidence given by Professor Tim Lenton suggesting that the global warming produced by Arctic methane would only amount to 0.1 degree or less, by the end of the century, can be dismissed if you accept that the sea ice cover will be removed as quickly as the PIOMAS data suggests. Even climatologist Professor David Archer of the University of Chicago, who recently claimed that AMEG concerns on methane were “much ado about nothing”, admits that a release of only one fifth of the 50 Gt of methane, which researchers Shakhova and Semiletov say could be released “at any time”, would take global warming over the 2°C limit established by IPCC as “dangerous anthropogenic interference” with the climate system.

But Professors Slingo and Lenton are not alone in their misleading analysis of the situation. We are appalled that there appears to be no recognition within any part of the scientific establishment, whether Government Departments, Research Councils, Institutes or Universities, of the imminence of extremely dangerous developments that would flow from allowing the present incipient runaway situation to develop in the Arctic. This amounts to a collective denial of danger – a collective burial of heads in the sand.

Similarly there appears to be little or no willingness to consider possible actions that could be taken immediately and within the next few years, as necessary in view of the rapidity with which the position in the Arctic is deteriorating.

So, what is to be done? Clearly a major effort has to be made immediately to cool the Arctic otherwise the whole of humanity is put at risk. Even if you, as a committee, concluded that the danger is overstated by AMEG, we would argue that the effort is worthwhile as an insurance policy. Suppose that this effort is made and proves to have been unnecessary, what has been lost? The technology for cooling the Arctic will have been developed for use at a later date or for a different circumstance.

Contrast the anti-precautionary approach espoused by Professor Slingo, Professor Lenton and the people from the modelling community who submitted evidence against geoengineering just before our hearing. They would prefer to see nothing done immediately to cool the Arctic on the grounds that there is uncertainty in the situation, and it is not yet proven whether (i) the Arctic sea ice is disappearing as rapidly as AMEG warns, and (ii) the methane threat is as great as AMEG warns. This is extraordinary for people who one would expect to espouse a precautionary principle in government, as surely they would in any other situation where there is a risk to millions of lives. Unless these people can prove that there is no risk arising from collapse of sea ice and escalation of methane emissions, which clearly they cannot, the committee has a responsibility to advise government that measures to cool the Arctic need to be taken on a precautionary principle.

Governments are expected to protect their own citizens on this principle, even if the danger is not proven. We would like to quote Article 3, paragraph 3, from the UNFCCC Convention, article 3, paragraph 3:

"3. The Parties should take precautionary measures to anticipate, prevent or minimize the causes of climate change and mitigate its adverse effects. Where there are threats of serious or irreversible damage, lack of full scientific certainty should not be used as a reason for postponing such measures, taking into account that policies and measures to deal with climate change should be cost-effective so as to ensure global benefits at the lowest possible cost. To achieve this, such policies and measures should take into account different socio-economic contexts, be comprehensive, cover all relevant sources, sinks and reservoirs of greenhouse gases and adaptation, and comprise all economic sectors. Efforts to address climate change may be carried out cooperatively by interested Parties." (Our underlining)

Note that AMEG considers that the cooling of the Arctic should be seen as one of many efforts to bring the atmosphere and oceans back towards their pre-industrial state, especially since such efforts reduce both immediate and longer-term risks arising from Arctic warming, sea ice retreat and methane release. AMEG is fully supportive of these efforts.

Why do these intelligent people from the modelling community seem to view all geoengineering as intrinsically dangerous? That may be the view in the media and among many environmentalists, but these scientists should be capable of a more rational assessment of each technique on its merits, on the limited scale as required for cooling the Arctic.

The candidate techniques AMEG proposes are all based on natural phenomena that can be observed. They can be switched off if and when any dangerous side-effects become apparent. There is nothing intrinsically dangerous about geoengineering – mankind has been doing it for millennia by altering the environment, albeit inadvertently.

Let’s look on the positive side. Cooling the Arctic and saving the sea ice has the obvious benefit of saving an entire ecosystem. Furthermore common sense suggests that geoengineering will tend to make things better because it is reversing the trends resulting from regional warming. One of the main effects of Arctic warming has been to cause disruption of regional weather patterns in the Northern Hemisphere, with more weather extremes and less long-term predictability of the weather. This has can only have had an adverse effect for farmers who rely on annual cycles like the monsoons. Thus cooling the Arctic should improve this situation. Yet Professor Slingo, in her oral evidence, states that, like the climate forcing from CO2 emissions, geoengineering will have "huge ramifications" implying that it is likely have serious side effects. Of course the very modelling that can be used to anticipate such side effects can also be used to avoid them, by adjusting the parameters of the techniques to be used (see note below). Thus modelling has an important part to play in the successful deployment of geoengineering.

Note: Each geoengineering technique has adjustable parameters, to allow the technique to be tailored to a particular situation. In the case of stratospheric aerosols, the height, latitude and time-of-year for the release of aerosol (or aerosol precursor) can be adjusted for maximum positive effect and minimum negative effect, using models to estimate these effects in advance. In the case of techniques to brighten or remove tropospheric clouds, more localised effects can be obtained; and parameters can be adjusted for different locations of deployment giving a great deal of flexibility as well as control.

Now we have no option other than to employ our best technology and expertise to get out of the crisis situation we have got ourselves into.

We respectfully suggest that modellers should turn their attention to modelling the effects of different geoengineering techniques, showing how unwanted side-effects can be minimised and working out how best to use various techniques in combination. This would be a useful contribution to the enormous challenge now faced to cool the Arctic. They must stop lulling the climate change community, and hence governments, into a false sense of security with their obsolete models which don't take account of reality.

In the light of the above we are writing to plead that you immediately alert the Prime Minister and his cabinet to the above conclusions: how the deteriorating situation in the Arctic has extremely threatening implications for all mankind if measures are not immediately adopted to cool the Arctic in order to reverse the current trends of retreating sea ice, escalating methane release and disruption of Northern Hemisphere climate. We realise that, under normal circumstance, we should wait for your report; but this is no ordinary situation. The sooner measures to cool the Arctic can be taken, the better. This is a daunting challenge, perhaps the biggest ever faced by humanity, but it can be met if there is a determined and concerted effort over the coming weeks and months by top scientists, engineers and yes modellers, tasked specifically to deal with the problems in the Arctic.

Only a directive from the highest levels of government is capable of initiating the programme of action required. The UN and all world governments must be alerted to the perilous situation now exposed.

Traditionally governments have tended to react to events rather than forestall them. But in this case we risk sliding irreversibly into ultimate climate catastrophe. We are close to a point of no return. Not to act as quickly as possible to halt the slide would be an abject failure of the most primary responsibilities of government. And, because such a catastrophe would threaten the life of every person on the planet, not to act would also be suicidal.

We implore the committee to give its full and serious attention to the challenge that this inquiry has thrown up, a challenge that whilst embracing the Arctic environment in its essence goes far beyond that in its enormously far-reaching implications for the rest of the planet. The committee has a unique opportunity to change the course of history.

John Nissen, Chair of AMEG

29th June, 2012

Appendix – “Life in 2032”

One of the questions raised at our hearing on 21st February concerned what life would be like in 20 years’ time, i.e. by 2032. We have considered this in respect of different scenarios, depending on methane emissions. We estimate that the Arctic is warming at about 1 degree per decade, around five times faster than the rest of the planet, and this is mainly because of sea ice retreat and more open water to absorb solar energy. In 10 years, i.e. by 2022, PIOMAS volume data suggests that the Arctic Ocean will be essentially free of ice for 6 months of the year, and the Arctic will then be warming at about 4 degrees per decade. The Arctic temperature will be 5 or 6 degrees hotter than today. The disruptive effect on Northern Hemisphere weather systems will be traumatic, leading to severe food shortages for all and starvation for millions if not billions of people.

If in addition there were an early release of the 50 Gt of methane that Shakhova and Semiletov say could be released from the East Siberian Arctic Shelf “at any time” (due to seabed warming and the instability of methane-holding structures), then we could expect over 3 degrees of global warming by 2032, liable to start runaway methane feedback. Not only would we be facing world-wide starvation but probably global conflict as well.

On the other hand if geoengineering and other measures were successful in cooling the Arctic sufficiently to bring back the sea ice to its pre-2007 volume and extent, then growth of methane emissions into the atmosphere would almost certainly be curtailed and the dreaded methane feedback avoided. The weather systems in the Northern Hemisphere weather systems would be stabilised, allowing the world farming community to plan for providing a growing world population with food. The spread of insect-born disease would be slowed. Conflicts arising from degraded environments would be reduced. And we would have more time to solve the underlying problems to ultimately remove the requirement to use geoengineering technology.

Tolerability of life in 2032 will thus depend on whether governments act quickly in response to today’s rapidly deteriorating situation by taking measures to cool the Arctic.

---

Editor's note: Above is a copy of the 31st submission to the Protecting the Arctic inquiry of the U.K. Environmental Audit Committee.  Submissions to date are listed below, with links to videos and submissions highlighted in yellow that are particularly relevant to points brought up by the Arctic Methane Emergency Group (AMEG). 

01 Professor Peter Wadhams

02 The Arctic Methane Emergency Group   (add comments here)

• Parliament TV: watch 21 February 2012 meeting
• Oral evidence: read 21 February 2012 transcript   

03 The Remote Energy Security Collaborative

04 Client Earth and Environmental Protection UK

05 Greenpeace

06 The Natural Environment Research Council

07 The Centre for Ecology and Hydrology

08 Platform

09 WWF-UK

10 The Scottish Marine Institute

11 Professor Clive Archer

12 The International Polar Foundation UK

13 The Joint Nature Conservation Committee

14 The UK Government

15 Professor Klaus Dodds, University of London

16 Shell International Ltd

17 The International Fund for Animal Welfare

18 The Arctic Advisory Group

19 Greenpeace

20 Professor John Latham et al

21 The Geological Society

22 Prof S Salter

23 Cairn Energy PLC

24 The Met Office

• Parliament TV: watch 14 March 2012 meeting
• Oral corrected evidence: read 14 March 2012 transcript

25 Cairn Energy PLC, Supplementary

26 Professor Peter Wadhams, Supplementary   (add comments here)

27 Shell, Supplementary

28 Cairn Energy

29 Letter submitted by Lord Taylor of Holbeach, Parliamentary Under Secretary, Defra

30 Chair of the Sustainable Development Working Group of the Arctic Council

31 Supplementary written evidence from John Nissen, AMEG    (add comments here)

When the sea ice is gone

How long do you think it will take for most sea ice in the Arctic to disappear? How much change in temperature you think this would result in? 

Below an educated guess from some of the members of the Arctic Methane Emergency Group. 

Professor Peter Wadhams

Peter Wadhams Sc.D., Professor of Ocean Physics
and head of the Polar Ocean Physics group at the
University of Cambridge, U.K., researching effects
of global warming on sea ice, icebergs and oceans

My own view of what will happen is:

1. Summer sea ice disappears, except perhaps for small multiyear remnant north of Greenland and Ellesmere Island, by 2015-16.
2. By 2020 the ice free season lasts at least a month and by 2030 has extended to 3 months.
3. September sea surface temperatures are already elevated by 6-7°C over continental shelves of Arctic. As shrink back continues, the newly exposed surface water over abyssal depths warms up less in a single summer (say 2-3°C) because of deeper surface water layer (150 m) than over a shelf (50 m).
4. The 6-7°C warming over the shelves causes offshore permafrost to shrink back and vanish over about 10 years. During this time there is elevated methane emission from offshore and from onshore warming, and global warming rates increase by about 50%.
5. Result is that bad effects forecast for end of century (4°C warming worldwide, 10°C in Arctic) actually occur by about 2060. Speed of change is catastrophic for agriculture; warfare and population crashes ensue.
6. Late in the day, the rapidly disintegrating civilised world tries desperate technofixes for warming and resource depletion, e.g. widespread use of nuclear power (thorium cycle), geoengineering. This may work, and bring us back from the brink of destruction after heavy losses.

Paul Beckwith

Paul Beckwith, B.Eng, M.Sc. (Physics),
Ph. D. student (Climatology) and
Part-time Professor, University of Ottawa

My projections for our planet conditions when the sea-ice has all vanished year round (PIOMAS graph projects about 2024 for this; I forecast 2020 for this) are:

• Average global temperature: 22°C (+/- 1°C)
  (rise of 6-8°C above present day value of about 15°C)
• Average equatorial temperature: 32°C
  (rise of 2 °C above present day value of 30°C)
• Average Arctic pole temperature: 10°C
  (rise of 30°C above present day value of -20°C)
• Average Antarctica pole temperature: -46°C
  (rise of 4°C above present day value of -50°C)
• Water vapor in atmosphere: higher by 50%
  (rise of 4% over last 30 years, i.e. about 1.33% rise per decade)
• Average temperature gradient from equator to North pole: 22°C
  (decrease of 28°C versus present day value of 50°C)
• Very weak jet streams (driven by N-S humidity gradient and weak temperature gradient as opposed to existing large temperature gradient)

- Result: very fragmented, disjointed weather systems

- Basic weather: tropical rainforest like in some regions; arid deserts in others with few regions in between

Note: This scenario would require significant emissions of methane from the Arctic. Without this methane, the scenario would still occur but would take longer. Disclaimer: Best guess and subject to rolling revisions!

Peter Carter

Dr. Peter Carter, MD, Canada
climate-emergency-institute.org

If methane is the main driver of natural end glacial warming rather than carbon dioxide, projections of global temperature increases are out by orders of magnitude.

On sea ice:
According to Tim Lenton’s opinion that 2007 was the tipping point, the start of ice free summers would begin @2015 on a new linear trajectory. As we know the trajectory is not linear, it would probably be earlier. As most of the models project possible abrupt loss, I assume it could be any year now.

Whatever the additional warming may be [because of already unavoidable committed warming], the multiple cascading Arctic positive feedback domino effect is already unstoppable except by cooling. 

Sam Carana

Already now, temperature rises and levels of greenhouse gases are higher in the Arctic than elsewhere. The prospect is that we'll lose most sea ice within a few years, resulting in a lot more sunlight to be absorbed, adding to the temperature rise in the Arctic. 

This would push up Arctic temperatures by over 10°C within a few decades, but in some places such rises could occur in a matter of years, rather than decades. 

Most worrying is that such intense local warming in the Arctic can cause large abrupt methane releases from sediments. This would add a lot of additional warming that would result in massive crop losses globally, threatening global fresh water supply and causing extinction at massive scale. 

Clearly, action must be taken to reduce the danger that this will eventuate.


John Nissen 

John Nissen, MA (Cantab) Natural Sciences, 

Director of Cloudworld Ltd, U.K., Chair of
Arctic Methane Emergency Group (AMEG)

Of late, I have been basing my estimates of Arctic warming on a current rate of 1 degree per decade, doubling after sea ice collapse, and doubling again when ice is gone for five or six months of the year. Looking at PIOMAS data, I think we can safely assume 2015 for the first doubling, and around 2020 for the second doubling. This means that between 2015 and 2020, the rate would be 2°C per decade, i.e. 1°C per 5 years. After that, it would double to 4°C per decade, up to 2030. That gives 5°C warming over 15 years.

I am now wondering whether 1°C per decade is too small, since Peter says that the water has warmed 6-7°C. However 1°C per decade is already at least 5x global warming, reckoned to be at less or equal to 0.2°C per decade.

If today, there has been 0.8°C global warming temperature rise, then, by 2030, global warming will be around 1.2°C, neglecting methane and Arctic warming. If we take Flanner's higher figure of ~4 W/m2 increase, for the Northern Hemisphere, when sea ice has gone, then that is ~2 W/m2, globally. According to Hansen net the current net forcing imbalance is under 1 W/m2, producing the 0.2°C per decade, and nearly 1.0 degree global warming temperature rise by 2020. With complete loss of snow and ice, we'd only be doubling the global warming rate. Suppose we double the rate from 2020 to 2030, then the global warming temperature rise would be around 1.4°C by 2030.

A temperature rise of 1.4°C doesn't seem too bad, but then we have the disruptive effect of the Arctic warming disrupting the NH weather systems. This is already having a serious effect, so could be pretty catastrophic by 2020, let alone 2030.

Now we add in the methane, and there's more uncertainty, except things are going to be worse, and could be a lot worse, especially if that 50 Gt of methane comes out of ESAS this decade. That could send global forcing up to around 9W/m2 (averaged over 20 years?), and warming rate up to 2°C per decade, giving us over 3°C global warming temperature rise by 2030 in the worst case. So we'd be well beyond the so-called safety limit of 2°C!

I agree with Peter that some dramatic increase in methane emission is inevitable, so my conservative estimate would be an additional 400 Mt per year by 2020. This would nearly double the methane forcing by 2030, from current 1W/m2 (including indirect effects) to around 2W/m2. This would add a temperature rise of 0.1°C, taking the total from 1.4 to 1.5°C.

So my conclusion on global warming temperature rise is between 1.5°C and 3°C by 2030, while the Arctic warms at least 5°C above current temperatures. We must not go there! Geoengineering is essential!

BTW, the warming in the Arctic would guarantee collapse of the Greenland Ice Sheet this century, adding ~7 metre sea level rise and probably triggering the collapse of the WAIS adding a further 7 metres or so.

 Douglas Spence - Software Engineer,
interested party and concerned citizen 

Douglas Spence 

Now

1. Even with the Arctic ice in the present state increasingly extreme weather is already moving us closer to a point of increasing risk to agricultural output.

2. For the last few years extreme weather has worsened year on year and since we have positive feedback processes in progress we have no reason to suppose this will do anything but accelerate rapidly.

2012-13

3. I expect significant to majority sea ice loss to occur in either 2012 or 2013, and expect this to dramatically worsen the weather, causing immediate stress to global food supplies. Combined with weak economic conditions we will see stress in countries dependent on food imports or aid triggering more "Arab spring" moments in previously stable regimes. Movement of refugees will cause knock on effects in neighbouring regions.

4. Modern civilisation is fragile and dependent on global supply chains that can be disrupted both by weather and politics. We will experience an increasing incidence of problems maintaining normal operation in technologically advanced societies. There is the potential for conflict in the Arctic as new resources open up.

5. Other positive feedbacks such as methane release and forest burn off will accelerate.

2014-15

6. I expect total sea ice loss will occur during summer in either 2014 or 2015. By this time I expect agricultural output to have declined to a point where food supplies are inadequate and famine and conflict are rife. Farmers will not know what to plant or when and even acquiring seed from other climatic regions may be problematic.

7. Social conditions will be comparable to the Holomodor. People will try to eat anything and everything - earthworms, insects, each other - even in some cases their own children. Nation states will fragment and reform into smaller and increasingly violent competitive groups fighting over rapidly diminishing resources. Maintaining the supply chains required for the operation of modern technology including agriculture will be largely impossible.

8. If we see widespread war before nation states fragment there is a possibility of the use of nuclear and genetically enhanced biological weaponry. Whether through war or famine the human population will be in freefall.

2016+

9. The climate will continue to worsen as more heat flows into the system and this will become the new threat to survivors as population density becomes too low to sustain conflict. Most survivors will be eliminated, leaving the human race on the brink of extinction. A majority of the planet will cease to be habitable. The deserts will greatly expand, though this will help balance the planets thermal budget. Very few people will live to see the Arctic sea ice entirely gone throughout the year or the ruined cities drowned in the rising sea.

10. Assuming the collapse is as rapid and severe as I expect – I would expect the human population to collapse below the new carrying capacity of the planet and therefore for resource pressure to lighten once a sufficient number of people die (granted with few useful resources left and uncertainty about precisely which regions would be good prospects).

Finally

Theoretically there will be some isolated and scattered areas where the climate is still habitable, resources are sufficient and some form of agriculture can be practised. If small groups of people make it to these areas, there is a theoretical chance over many generations to recover civilisation, albeit at great disadvantage.

Disaster taxa will rapidly proliferate into the empty ecosystem, leaving the return of biodiversity to occur over a few million years, bringing the sixth great mass extinction to a close.

NB Since we are at a point where weather is a key effect, allow +/- 1 year for (good/bad) luck.

Malcolm Light

Malcolm Light, PhD, University of London
Earth science consultant

If left alone the subsea Arctic methane hydrates will explosively destabilize on their own due to global warming and produce a massive Arctic wide methane “blowout” that will lead to humanity’s total extinction,  probably before the middle of this century. AIRS atmospheric methane concentration data between 2008 and 2012 (Yurganov 2012) show that the Arctic has already entered the early stages of a subsea methane “blowout” so we need to step in as soon as we can (e.g 2015) to prevent it escalating any further.

The Arctic Natural Gas Extraction, Liquefaction & Sales (ANGELS) Proposal aims to reduce the threat of large, abrupt releases of methane in the Arctic, by extracting methane from Arctic methane hydrates prone to destabilization.

After the Arctic sea ice has gone (probably around 2015) we propose that a large consortium of oil and gas companies/governments set up drilling platforms near the regions of maximum subsea methane emissions and drill a whole series of shallow directional production drill holes into the subsea subpermafost “free methane” reservoir in order to depressurize it in a controlled manner. This methane will be produced to the surface, liquefied, stored and transported on LNG tankers as a “green energy” source to all nations, totally replacing oil and coal as the major energy source. The subsea methane reserves are so large that they can supply the entire earth’s energy needs for several hundreds of years. By sufficiently depressurizing the Arctic subsea subpermafrost methane it will be possible to draw down Arctic ocean water through the old eruption sites and fracture systems and destabilize the methane hydrates in a controlled way thus shutting down the entire Arctic subsea methane blowout.

AMEG presentation, London June 16, 2012

On June 16, 2012, the Arctic Methane Emergency Group (AMEG) gave a presentation on the situation in the Arctic at the Campaign against Climate Change (CaCC) conference (see video below).


AMEG from Nick Breeze on Vimeo.

Below an web-copy of the AMEG flyer distributed at the conference:

           

EVERYTHING depends on you helping the Arctic

* the Arctic is warming ever faster ⁽¹⁾

* the sea ice volume is plummeting ⁽²⁾

* which prefaces a collapse in sea ice extent ⁽³⁾

* Arctic warming already disrupting climate,
  causing unpredictable weather for farmers ⁽⁴⁾

* already escalating emissions of methane ⁽⁵⁾
  from vast store in Arctic seabed ⁽⁶⁾

* and, as methane is a potent greenhouse gas ⁽⁷⁾
  risks runaway global warming. ⁽⁸⁾

  Demand action to pull back from the brink

Demand that governments assess the threat
from Arctic methane release, and
Demand swift action to COOL THE ARCTIC.

   FIND OUT MORE - and do your part

Join our campaign at www.ameg.me

 Contact: AMEG chair, John Nissen johnnissen2003@gmail.com 
 email with subject line: AMEG campaign

The URL to the presentation is: http://vimeo.com/44171386

For more background, see the recent Message from the Arctic Methane Emergency Group (AMEG) and the references below: 

1. The Arctic is warming ever faster
http://arctic-news.blogspot.com/p/how-much-time-is-there-left-to-act.html

2. Sea ice volume is plummeting
http://arctic-news.blogspot.com/2012/06/arctic-sea-ice-volume-on-track-to-reach.html

3. which prefaces a collapse in sea ice extent
http://arctic-news.blogspot.com/2012/04/supplementary-evidence-by-prof-peter.html

4. unpredictable weather for farmers
http://global-warming.gather.com/viewArticle.action?articleId=281474977688104

5. escalating emissions of methane
http://arctic-news.blogspot.com/2012/05/striking-increase-of-methane-in-arctic.html

6. from vast store in Arctic seabed
http://arctic-news.blogspot.com/p/need-for-geo-engineering.html

7. methane is a potent greenhouse gas
http://arctic-news.blogspot.com/2012/05/video-and-poster-methane-in-arctic.html

8. runaway global warming
http://geo-engineering.blogspot.com/2011/04/runaway-global-warming.html

Protecting the Arctic

U.K. Environmental Audit Committee, hearing February 21, 2012

Peter Wadhams (left) and John Nissen (right)

The meeting started at 2.12pm and ended at 4.08pm.

The video below starts with a presentation by Professor Tim Lenton, University of Exeter, who is not a member of the Arctic Methane Emergency Group. The video further features Professor Peter Wadhams, University of Cambridge, and John Nissen, Chair, Arctic Methane Emergency Group.

Click on Read More if you don't see the video (it may take some time for the video to start), the transcript and written submission below.

AMEG Submission to U.K. Environment Audit Committee, for hearing on 21st February 2012

Oral presentation to 'Protecting the Arctic'

By John Nissen, AMEG Chair

1. Introduction

“Thank you, Chair, for extending this opportunity to present evidence on behalf of the Arctic Methane Emergency Working Group - a collaboration of scientists, engineers and communicators.

As you have just heard from my colleague Professor Wadhams – and is stated in our written submission – the imminent collapse of Arctic sea ice poses a new emergency situation, which threatens an irreversible transition towards abrupt and catastrophic climate change – a point of no return which must be avoided at all costs. We consider this a planetary emergency – a matter of national and international security of the highest order.

Professor Wadhams has clearly indicated the devastating consequences that will follow a collapse of sea ice, in terms of ocean circulation, weather patterns, flood and food supply. I am here to address the issue of methane, as this will escalate events if not addressed by similar means: cooling the Arctic.

2. Some facts about methane

Methane is the main constituent of natural gas. As a GHG, methane is 72 times more potent than C02 over the first 20 years, weight for weight.

The Arctic has the potential to release a staggering amount of methane – triple the weight of anthropogenic CO2 in the atmosphere. Because of its potency as a greenhouse gas, a release of just 1% of this methane – 35 billion tons - would triple the current rate of global warming.

3. What is happening?

The scenario we describe in our written submission and brochure is one of simple common sense: this vast quantity of methane is contained in and by the ice, as the ice thaws the methane is released.

About half of the Arctic methane is held in or by ice below the seabed. This methane appears to be in a critical condition. As the sea ice disappears, the whole Arctic Ocean is heating more rapidly, leading to release of methane in ever larger quantities. Because of its greenhouse effect, this methane can then cause global warming to escalate out of control. Then it's difficult to imagine how civilisation could survive beyond a few decades.

The plausibility of such devastating methane release has long been recognised, although the sheer speed of events now evident has taken everybody by surprise and disbelief.

The emerging evidence indicates the conditions are developing to bring this nightmare scenario into reality. As a result of the sea ice retreating, the Arctic is now warming at least 4 times faster than other parts of the world, and with seabed temperatures rising as much as 3C, methane is being released in increasingly large quantities.

4. ESAS methane instability

The East Siberian Arctic Shelf is the largest continental shelf area on the planet and contains most of the Arctic Ocean’s methane.

Ongoing expeditions have reported increasing instability in this shallow area of the Arctic, with plumes of methane a kilometre wide erupting from the ocean floor and reaching the surface. The instability of methane over the whole region is such that a sudden release of 50 billion tons is possible at any time. That would cause global warming to speed up by four or five times, overwhelming current international efforts to keep global warming within the so-called “safe” limit of 2 degrees.

The prospect of drilling being allowed here is terrifying. Note that unstable sub-sea methane was the cause of the Deepwater disaster.

We must heed these clear signals that vast undersea methane stores are becoming unstable in the Arctic.

5. Emergency action to avoid passing point of no return

We are close to a point of no return – no going back – a point where we have escalating temperatures in the Arctic and escalating release of methane, with global warming spiralling upward, out of control, while the prospects of our own survival spiral downwards.

What can be done? We have the expertise, we have technological know-how, and we have the inherent capability to confront a threat of this magnitude. All we need is the political leadership – the kind of leadership that Churchill showed in WW2. Instead of a human enemy we face ever increasing forces of nature turned against us.

We have have to take immediate and drastic action - as Professor Wadhams says: next September could see the Arctic virtually sea ice free - at which point the consequences will start to move out of our control.

Our window of opportunity has to be measured in months rather than years.

If we want to protect the Arctic we need to cool it – and quickly.

This matter must be raised immediately at the highest level in government.

Written submission AMEG

Note that this written submission will be presented orally by two people: Professor Peter Wadhams focusing on sea ice retreat and John Nissen dealing with methane and required actions.

'Protecting the Arctic'

This is a submission on behalf of the Arctic Methane Emergency Group (AMEG) [1], which includes among its founding members Peter Wadhams, Professor of Ocean Physics, Cambridge; Stephen Salter, Emeritus Professor of Engineering Design, Edinburgh; and Brian Orr, PhD, former Principal Science Officer at the UK DoE (as was).

Most geoscientists like to separate policy from science - so they will state what is happening to the Earth System but not suggest the kind of interventions that could prevent the situation from gradually deteriorating. Especially the subject of the deliberate intervention known as geoengineering has been taboo until very recently, and it is still treated with great suspicion. However this perception of gradual deterioration, where the timescale is over decades or longer, has totally changed with the discovery of both the extraordinarily rapid decline of sea ice and the possibility of sudden discharge of gigatons of the potent greenhouse gas, methane, from sediments at the bottom of the Arctic Ocean. (Methane is the main constituent of natural gas.)

AMEG was formed from a group of scientists, engineers and communicators, to alert the world to the dangers that have to be faced, and the need for immediate and drastic action to reduce the risk of passing a point of no return with the sea ice – a point after which the Arctic Ocean would become free of sea ice for much or all of the year without any possibility of restorative intervention. Following such a decline of sea ice, the Arctic would continue warming but at a much greater rate than hitherto, causing an escalation of methane emissions from both marine and terrestrial sources and risking runaway (abrupt) global warming.

Passing such a point of no return would be catastrophic for the whole of humanity, as, inexorably, global temperatures would spiral upwards and food production downwards.

Therefore we consider our present situation is extremely dangerous and warrants the designation of "planetary emergency".

We see only one way to avoid passing this point of no return, which is to intervene by cooling the Arctic, principally by using geoengineering techniques starting immediately.

We now consider the imminence of sea ice collapse and the consequences in more detail.

Sea Ice Retreat

No doubt the Committee would support the precautionary principle that, if there is a reasonable likelihood of a catastrophic event occurring, governments should try to take what precautions they can in order to anticipate or mitigate it. There were very complacent consensus statements about the Arctic sea ice from the IPCC in the AR4 report of April 2007, saying the sea ice was very likely to last beyond the end of the century. Furthermore the policy of emissions reduction, to keep within a target global warming of 2 degrees C, has been based on there not being a tipping point of the Arctic sea ice and there not being a significant rise in methane level such as to rival CO2’s climate forcing.

Since the IPCC reported it has become widely accepted that Arctic amplification of global warming is largely due to the albedo “positive feedback” effect of sea ice retreat: the melting of sea ice exposes the water to warming in the sunshine, which leads to further melting in a vicious cycle (no doubt mentioned in Tim Lenton’s submission). Quantification of this affect has only very recently been attempted, in a paper to the 2011 AGU by Hudson [2]. The startling conclusion is that the rate of warming of the Arctic could double or even triple, once the Arctic Ocean is ice-free in September. And it could double again, once the ocean is ice-free for half the year. But the timescale makes this all the more worrying.

The annual average extent of the Arctic sea ice cover has been diminishing since the 1950s. At first this was at a slow rate, some 3% per decade, but since the early 2000s has accelerated at 10% per decade. The retreat is especially rapid during the summer months. It is accompanied by a thinning, which has been shown by measurements from submarines to be a very rapid one, with a reduction of 43% in mean ice thickness between the 1970s and early 2000s. So far the record year for summer ice retreat is 2007, although it was almost matched by 2011. But the inexorable thinning that accompanies the retreat has caused the summer volume of the ice cover to the lowest ever last year, less than 30% of its value 20 years ago [3a]. The trend in volume is such that if one extrapolates the observed rate forward in time, by following an exponential trend line, one obtains a September near-disappearance of the ice by 2015. However, following an equally valid logarithmic trend, one finds that summer 2012 and 2013 are the most likely years for such a collapse [3b]. Thus one has to conclude that, on current best evidence, there is a distinct possibility of a collapse in extent leaving relatively little ice this summer, and a collapse is likely by 2015.

Subsequently the ice-free period begins to stretch over a greater number of months, with 5 months ice-free within about three years according to the extrapolation of trends for different months [3c]. Already the summer retreat is allowing the temperature of the ocean to rise significantly in summer all over the shelf seas, up to 4-5C, and this is liable to continue at an increased rate. The warming is already causing undersea permafrost to thaw and release trapped methane in large plumes, increasing the atmospheric methane load and threatening to accelerate global warming [4]. All these changes are based on observations, not models, so one is forced to consider urgently what response is appropriate. This new emergency situation, which threatens abrupt and catastrophic climate change, cannot be ignored.

Saving the sea ice

The discovery of rapid decline of sea ice and its apparent effect to escalate emissions of methane from ESAS has taken the scientific community completely by surprise. Hitherto attention has been focussed on sea ice extent, but recent evidence shows a collapse in extent could occur this year or in the next few years. Following a collapse in extent, the climate forcing from the “albedo effect” could more than double. And if the Arctic Ocean were to become ice free for six months or more, the climate forcing could double again. And when there is no more ice to melt, the heat flux all goes into heating the water. The possibility of sea ice collapse this summer is why we urge the government to consider what can be done immediately and consider the planning, development and deployment of geoengineering techniques [5] for deployment as soon as possible.

Note that the loss of sea ice would destroy an entire ecosystem and habitat, with severe implications on biodiversity, while also destroying the way of life for indigenous peoples. Thus geoengineering can be seen to have remarkable benefits when used in this context.

Also note that as the Arctic heats, there is increasing instability of jet stream and weather systems, leading to extremes of weather, already being observed.

Successful geoengineering to cool the Arctic should help to stabilise the Greenland ice sheet, slow the glaciers and reduce the risk of metre or more sea level rise, of particular concern to countries with low-lying populated regions.

Methane feedback

While the sea ice has been retreating, there have been growing signs of critical instability of undersea methane in the Arctic Ocean, especially in the East Siberian Arctic Shelf (ESAS) area where vast plumes of methane have been seen bubbling to the surface [4]. Research in this area has been limited, but it appears that emissions have risen dramatically over the past few years, and it is thought that this could be as a result of the water above the seabed reaching a temperature threshold. The exact mechanism for this accelerated methane release is not understood (and there is some controversy over appropriate modelling), however governments must act according to best evidence in a precautionary manner, and take a continued escalation of methane emissions under sea ice retreat as a matter for extreme concern.

Shakhova and Semiletov estimate that 50 gigatonnes of methane are available for immediate release from ESAS [5], and, if this amount were released into the atmosphere, the methane level would rise by eleven or twelve times, causing global warming to rapidly escalate, in turn causing more methane emissions in a feedback loop.

Such an escalation of methane emissions would cause abrupt and catastrophic climate change within a few decades. Even much slower emissions (e.g. 1% of potential methane over 20 years) could put the climate system out of any control for climate change mitigation with catastrophic consequences sooner or later.

We bring your attention to the facts that there is no likelihood of even a reduction in global emissions of CO2 in the foreseeable future; both emissions and concentration of CO2 are increasing at record rates; and the atmospheric methane level has been rising since 2007 after a decade of little change [7]. The most recent evidence suggests that this latest rise could be at least partially due to methane emissions from shallow seas in the Arctic, see below.

Other evidence

In just the past few years the loss of Arctic snow and ice and the associated albedo effect has nearly doubled; Arctic subsea methane hydrate is venting to the atmosphere [8]; permafrost carbon has been found to be double what was previously thought [9]; and large amounts of nitrous oxide are being released from thawing permafrost [10].

The catastrophic risk of global warming leading to very large emissions of methane from large Arctic carbon pools, especially from subsea methane hydrate, is documented in the 2007 IPCC assessment [11].

This situation is documented by the US Investigation of the Magnitudes and Probabilities of Abrupt Climate Transitions (IMPACTS) project [12]. Since this overview was published in 2008 the Arctic situation has deteriorated to the point that we need no more research to confirm the planetary emergency. In particular it had been assumed that Arctic methane hydrate was stable this century and that when hydrate did destabilize by ocean warming it would not vent to the atmosphere. Recent observed findings that methane is venting to the atmosphere disprove these assumptions. On land the Arctic permafrost carbon pool has been found to be double the estimates.

The Arctic is undergoing very rapid and accelerating changes. In combination, these changes imply a strong positive feedback to increased climate warming through increased greenhouse gas (GHG) emissions, decreased albedo, and hydrology and ocean circulation changes (Chapin et al., 2005 [13]; Lawrence and Slater, 2005 [14]).

These positive physical and biogeochemical feedbacks can, with high probability, cause a change in state over a period of less than a decade or two in terrestrial ecosystems climate forcing that is several times greater than is the change in radiative forcing from fossil fuel burning. There is then the likelihood of methane feedback, whereby the radiative forcing leads to an increase in methane emissions, in a positive feedback loop – leading to abrupt and catastrophic climate change (Chu [15]).

The associated changes in terrestrial ecosystems composition, spatial distribution, and GHG dynamics are irreversible over millennia, comparable to the temporal scale of glacial-interglacial cycles. A degree of boreal/arctic feedback to warming has already been documented, (see Chapin et al., 2005 [13]).

The greatest single threat of the worst abrupt warming is from Arctic methane hydrate. In combination with all the other Arctic positive feedback emissions that are operant this is a planetary emergency. The current abundance of carbon stored in hydrates is generally believed to be greater than the recoverable stocks of all the other fossil fuels combined (Buffet and Archer, 2004 [16]; Gornitz & Fung, 1994 [17]), and methane is 72 times more potent as a greenhouse gas than is carbon dioxide over 20-year time horizons (IPCC, 2007a [18]). There is evidence that methane hydrate releases have caused abrupt climate changes in the past, such as the Palaeocene-Eocene Thermal Maximum 55 million years ago when the planet abruptly warmed 5-8K (Dickens, 2003 [19]). There is also disputed evidence that hydrate dissociation greatly amplified and accelerated global warming episodes in the late Quaternary period (Kennett et al., 2000) [20]. The stability of the contemporary hydrate inventory to the unprecedented temperature rise from anthropogenic emissions is unknown. The Arctic contains hundreds of gigatons of methane hydrate with a time scale for release of decades, and the release is predicted to be abrupt at each location because the hydrates lie close to the edge of the gas hydrate stability zone defined by temperature and pressure. Plausible scenarios could lead to methane becoming more important than CO2 as a greenhouse gas on a time-scale of decades, with the associated warming leading to further hydrate dissociation, as well as terrestrial permafrost melting, which will release additional methane and be self-sustaining.

How to cool the Arctic quickly

The most cost-effective techniques involve reducing the sunlight falling on the Arctic, either by producing a fine haze of aerosol or fine-grain particles or by brightening clouds. As far as we know, neither technique has been tried on a large scale; but both techniques has natural analogues which suggest that they should be safe and effective, if their effects are modelled carefully so that their deployment avoid unwanted side-effects.

However, neither technique is sufficiently developed for immediate deployment. Thus we have to consider increasing existing cooling effects from aerosols and decreasing any factors that could have a significant short-term warming effect in the Arctic. Of particular interest is to curb inadvertent methane emissions and black carbon (commonly known as soot), especially at high latitudes [21]. Drilling for natural gas in the Arctic can produce a lot of methane leakage to the atmosphere and is not advisable until we have technology in place to cool the Arctic [22].

High risk developments in the Arctic

Although this is not a remit of AMEG, we would like to mention a hazard arising from drilling in the Arctic where there is methane hydrate, especially on the continental shelf edge. We have a concern that much of this hydrate has become unstable, as its stability zone has moved as a result of warming of the seabed [23]. Drilling can easily cause this hydrate to disassociate into methane gas and water explosively, which can be disastrous for any ship above, because it will sink in the reduced density of water filled with methane bubbles. But our main concern is that such a destabilisation of the hydrate can cause a slump with a tsunami-inducing force which could cause a chain reaction of destabilisation across the whole Arctic Ocean shelf margin. This margin contains many megatonnes of methane as hydrate, enough to start a methane feedback if a significant proportion were released in one go. Thus we urge that there is a halt on all drilling for methane hydrate in the Arctic until precautions have been developed and a proper risk assessment made.

Conclusions

We believe that the large positive feedback from loss of Arctic summer sea ice and snow albedo with Arctic subsea methane already venting is enough to advance the possibility of methane feedback taking hold from decades to years. The mandatory requirement to avoid a possible sea ice collapse this year, and point of no return, leads to an unprecedented engineering challenge.

The findings of our group were presented at AGU 2011, San Francisco, and we have discussed the latest evidence with leading experts in relevant fields. This evidence points ever more strongly to there being a planetary emergency, so we are striving to get this recognised and acted upon at the highest level in governments, and would welcome your support.

When there is so much at stake, it is the duty and moral obligation of governments to act on the precautionary principle to protect their own citizens [24]. By collaborating with others to protect the Arctic, a climate of cooperation can be engendered to protect the whole planet for the benefit of ourselves and future generations.

John Nissen, Chair of the Arctic Methane Emergency Group

Peter Wadhams, Professor of Ocean Physics at the University of Cambridge


References

[1] AMEG
http://arctic-methane-emergency-group.org

[2] Hudson (2011) - Albedo effect and Arctic warming
http://www.agu.org/pubs/crossref/2011/2011JD015804.shtml
http://www.npolar.no/npcms/export/sites/np/en/people/stephen.hudson/Hudson11_AlbedoFeedback.pdf

[3a] PIOMAS, September, exponential trend for sea ice volume
http://neven1.typepad.com/.a/6a0133f03a1e37970b0153920ddd12970b-pi

[3b] PIOMAS, September, trend lines compared
https://sites.google.com/site/arctischepinguin/home/piomas

[3c] PIOMAS, all months
http://neven1.typepad.com/.a/6a0133f03a1e37970b0153920dd89a970b-pi

[4] Vast methane 'plumes' seen in Arctic Ocean - The Independent
http://www.independent.co.uk/news/science/vast-methane-plumes-seen-in-arctic-ocean-as-seaice-retreats-6276278.html

[5] SRM geoengineering to cool Arctic
How to cool the Arctic - John Nissen, December 2011
http://arctic-news.blogspot.com/p/how-to-cool-arctic.html

[6] 50 Mt of methane from ESAS available for release at any time
http://www.cosis.net/abstracts/EGU2008/01526/EGU2008-A-01526.pdf

[7] Methane level over past century
http://www.esrl.noaa.gov/gmd/webdata/ccgg/iadv/graph/mlo/mlo_ch4_ts_obs_03437.png

[8] Sam Carana, Methane venting in the Arctic
http://arctic-news.blogspot.com.au/2012/02/methane-venting-in-arctic.html

[9] Sam Carana, Potential for methane releases
http://arctic-news.blogspot.com/p/potential-for-methane-release.html

[10] Elberling et al, 2010
High nitrous oxide production from thawing permafrost
http://www.nature.com/ngeo/journal/v3/n5/abs/ngeo803.html

[11] Risk of Catastrophic or Abrupt Change - IPCC AR4 WG 3 2.2.4
http://ipcc.ch/publications_and_data/ar4/wg3/en/ch2s2-2-4.html

[12] IMPACTS project
http://esd.lbl.gov/research/projects/abrupt_climate_change/impacts/tasks.html

[13] Chapin et al., 2005
Role of Land-Surface Changes in Arctic Summer Warming
http://www.sciencemag.org/content/310/5748/657.abstract

[14] Lawrence and Slater, 2005
A projection of severe near-surface permafrost degradation during the 21st century
http://www.agu.org/pubs/crossref/2005/2005GL025080.shtml

[15] Stephen Chu
Video on methane feedback
http://www.youtube.com/watch?v=oHqKxWvcBdg

[16] Buffet and Archer, 2004
Global inventory of methane clathrate: sensitivity to changes in the deep ocean
http://geosci.uchicago.edu/~archer/reprints/buffett.2004.clathrates.pdf

[17] Gornitz & Fung, 1994
Potential distribution of methane hydrates in the world's oceans
http://www.agu.org/pubs/crossref/1994/94GB00766.shtml
http://pubs.giss.nasa.gov/abs/go00200p.html

[18] IPCC - Global Warming Potential
Intergovernmental Panel on Climate Change (IPCC, 2007)
http://www.ipcc.ch/publications_and_data/ar4/wg1/en/ch2s2-10-2.html#table-2-14

[19] Dickens on PETM, 2003
Excess barite accumulation during the Paleocene-Eocene thermal Maximum: Massive input of dissolved barium from seafloor gas hydrate reservoirs
http://specialpapers.gsapubs.org/content/369/11

[20] Kennett et al. on methane excursions, 2000
Carbon Isotopic Evidence for Methane Hydrate Instability During Quaternary Interstadials
http://www.sciencemag.org/content/288/5463/128.abstract

[21] An analysis of short term measures to slow global warming
http://www.nature.com/news/pollutants-key-to-climate-fix-1.9816

[22] High emissions from gas field
http://www.nature.com/news/air-sampling-reveals-high-emissions-from-gas-field-1.9982

[23] U.S. Department of Energy - Drilling Safety and Seafloor Stability
http://www.netl.doe.gov/technologies/oil-gas/FutureSupply/MethaneHydrates/about-hydrates/safety-stability.htm

[24] UNFCCC Convention 1992, Article 3, point 3
http://unfccc.int/essential_background/convention/background/items/1355.php

Environmental Audit Committee
http://www.parliament.uk/eacom
The Environmental Audit Committee considers the extent to which the policies and programmes of government departments and non-departmental public bodies contribute to environmental protection and sustainable development, and it audits their performance against any sustainable development and environmental protection targets. Unlike most select committees, the Committee’s remit cuts across government rather than focuses on the work of a particular department.