Friday, December 7, 2012

AMEG Strategic Plan

2012-12-04

AMEG Strategic Plan


This strategic plan was prepared by the independent policy group, AMEG (the Arctic Methane Emergency Group), comprising a multidisciplinary team of leading scientific experts, system engineers, communicators and concerned citizens.


Purpose

The purpose of this document is firstly to warn the world of the extreme and imminent danger of global famine and ensuing strife created by rapid Arctic warming and precipitous sea ice retreat, and secondly to provide a strategic plan for handling this situation.

The international community is totally unprepared for the speed of change in the Arctic, the dramatic effects on global climate and the dire repercussions on food production.

The tendency among scientists and the media has been to ignore or understate the seriousness of the situation in the Arctic.  AMEG is using best available evidence and best available explanations for the processes at work.  These processes include a number of vicious cycles which are growing in power exponentially, involving ocean, atmosphere, sea ice, snow, permafrost and methane.  If these cycles are allowed to continue, the end result will be runaway global warming.

The situation is so urgent that, unless appropriate action is taken within a few months, the window of opportunity will be lost.  Adaptation to the consequences will be impossible, as famine spreads inexorably to all countries.

The situation is of unprecedented danger in the history of civilisation.  Humans are not psychologically prepared to deal with such mortal danger except by suppressing thoughts of it.  But we, as a human society, have to “get a grip” if we are to survive.

The good news is that AMEG believes that the emergency situation can be handled, but only if faced squarely and treated with focus, determination and urgency.  The international community must not only tackle the effects of a growing number and severity of weather extremes, tantamount to abrupt climate change, but must also tackle the underlying cause: a vicious cycle of Arctic warming and sea ice retreat.

Peoples of the world must be told the truth about the extreme danger that we all face.  Then there is a unique opportunity for all nations to pull together to fight the common “enemy”, which is the vicious cycle of Arctic warming and sea ice retreat.

Governments of the world must not pretend that there is no immediate crisis.  They must understand the chain reaction of cause and effect, and collaborate to protect all citizens.

Introduction

Abrupt climate change is upon us.  Extreme weather events are on the increase. Farmers are in despair.  Food prices are rising.  The UN climate change policy simply based on emissions reduction cannot deal with the immediate danger.  The UN and member governments should have acted years ago to avert the crisis now unfolding.  What has been happening in the Arctic has been completely overlooked, and now only drastic action to cool the Arctic has any chance of rescuing humanity.

A key factor is the Arctic sea ice, whose reflection of sunshine keeps the planet cool.  Remove the sea ice, and not only does the planet start to overheat, but the whole climate is suddenly changed.  The global weather systems, on whose predictability farmers rely, are dependent for their stability on there being a temperature gradient between tropics and the poles.  Remove the snow and ice at one pole, and the weather systems go awry and we have “global weirding”.  Furthermore, the weather systems get stuck in one place, and we get weather extremes: long spells of hot/dry weather with drought, or long spells of cold/wet weather with floods.

This global weirding has started with a vengeance.  The sea ice is rapidly disappearing.  The behaviour of the polar jet stream is disrupted.  Extreme weather events occur more often and with greater ferocity.  And the food price index climbs and climbs.

There is an obvious relationship between strife and food – if you starve a nation they will fight to get food.  This relationship has been pinned down by an organisation called the Complex Systems Institute, CSI.  They show that the food riots break out when the food price index rises above a certain critical level.  An example was the Arab Spring.



Figure 1 ~ A trend line analysis of CSI data

Figure 1 adds trend lines to the CSI data, the Rabobank Report forecast for UN FAO Food Price Index for June 2013 and the potential repeat of 2008 and 2011 at the elevated levels resulting from the overall underlying trend of line 1.

The current index is above the critical level.  Because of extreme weather events this year, the index is expected to rise again in 2013.  The UN’s food watchdog, the FAO (Food and Agriculture Organisation), forecast that the index will rise even further in 2014.  

Meanwhile the insurance industry is worried by the trend towards greater number and strength of extreme weather events, including hurricanes.  Note that Sandy’s cost was greatly amplified by the diversion westward at it approached the coast off New York.  Sandy had hit a jet stream blocking pattern.  The loss of Arctic sea ice is leading to this kind of unusual event become more frequent.  The insurers are worried, but governments should be even more worried, because extreme weather events will drive the food price index even higher.

The critical situation



Figure 2 ~ Connecting the dots and breaking the chain

As the sea ice retreats, exposed water absorbs more sunshine, heating the water and causing further melt of the sea ice in a vicious cycle.  This appears to be the dominant positive feedback loop in the Arctic, although snow retreat may contribute nearly as much to the warming of the Arctic generally in a second feedback loop.

A further feedback loop is ominous: as the Arctic warms, the thawing of land and subsea permafrost allows the discharge of growing quantities of the potent greenhouse gas, methane, which in turn causes further warming in a vicious cycle.  This cycle is not yet noticeable.  However there is over a trillion tons of carbon stored in permafrost in the form of organic material, which is liable to decompose anaerobically to form methane.  And the permafrost forms the cap on an even larger carbon store already in the form of methane.  Most scientists now accept that Northern Hemisphere land permafrost will thaw entirely this century.  There is the potential for the release of enough methane into the atmosphere to cause runaway global warming, with temperatures rising well over ten degrees C.

The most immediate negative impact of these cycles and the resultant rapid warming of the Arctic atmosphere is a disruption of polar jet stream from its normal behaviour, such that there are more frequent and more severe weather extremes experienced in the Northern Hemisphere.  This impact has grown so conspicuously over the past few years that we can honestly say that we are now experiencing abrupt climate change.  The result of this climate change is widespread crop failure and an ever deepening food crisis.

A measure of the worsening situation is the food price index.  This has spikes when the price of oil rises, but the underlying value has been rising steadily since 2006.  Today, the index is slightly more than the critical price level above which food riots are liable to break out – an example having been the Arab Spring.  Largely as a result of the crop failures this year, the FAO forecast that the index will rise higher in 2013 and higher again in 2014.  If the trend in weather extremes continues, then these figures could prove optimistic.  With a billion people on the edge of starvation today, we could see 2 billion by this time next year.  It will be a humanitarian disaster.  Furthermore, social unrest will rise, and economic growth and stability compromised in the developed and developing countries.

However there are longer term impacts and threats of Arctic warming, in particular (i) Greenland Ice Sheet destabilisation, (ii) accelerated methane discharge, (iii) loss of biodiversity and habitat, and (iv) heat absorption making it more difficult to keep to global warming targets.

As the snow and sea ice retreat from their levels in the 70s, more solar energy is absorbed.  Taking the 70s as the baseline (zero forcing), this year's retreat produced as much as 0.4 petawatts of climate forcing averaged over the year.  Much of this heat energy is retained in the Arctic, causing ice to melt and sea and land temperatures to rise.  As temperatures rise, there will be slightly more thermal radiation into space, dissipating some of this energy.  However most of this heat energy will slowly dissipate across the planet - and 0.4 petawatts is equivalent to half the forcing producing by anthropogenic CO2 emissions (1.6 watts per square metre).  Peter Wadhams has estimated that the sea ice retreat by itself is equivalent to the forcing from 20 years of CO2 emissions, thus making it much more difficult for the global temperature to be kept below the so-called safe limit of 2 degrees warming.

However these long term effects are somewhat academic, if the immediate impact is to raise food prices far above a safe level.

It is much easier to think about and quantify the longer term impacts of Arctic warming than the more immediate impacts.  This is a trap for the unwary.  Therefore AMEG is trying to bring the world's attention to the immediate impacts, as they turn out to be colossal even this year, and are likely to be worse in 2013 and even worse than that in 2014.

It is clear that abrupt climate change has started, but not in the way we had been told to expect.  Yes, there would be more climate extremes as the planet heated, but we were expecting a linear or near linear behaviour of the climate system, with gradual temperature change over the century.  Instead we have striking non-linearity, with exponential growth in frequency and severity of climate extremes.  This non-linearity is almost certain to have arisen from the exponential decline in sea ice, as shown in the PIOMAS sea ice volume trend.  The trend is for September ice to fall to zero by 2015.  Thus we can expect one month without sea ice in 2015, with the possibility for this event in 2014 or even in 2013.

Apart from volcanic eruptions and earthquakes with their step changes of state, the behaviour of the sea ice is possibly the most non-linear part of the Earth System because the melting is a threshold process.  Until recently it was not well understood how the retreat of sea ice could cause a commensurate increase in weather extremes.  But now it has become clear.

The retreat of sea ice is causing a non-linear rise in Arctic temperature, so that it is now rising at about 1 degree per decade, which is about 6x faster than global warming, reckoned to be rising at between 0.16 and 0.17 degree per decade.  The temperature gradient between the tropics and the Arctic has reduced significantly over the past decade, as a result of this so-called ‘Arctic amplification of global warming’.

It now appears that the polar jet stream behaviour is critically dependent on this gradient.  As the gradient diminishes, the jet stream meanders more, with greater amplitude of the Rossby waves and therefore with peaks further north and troughs further south.  This effect alone produces weather extremes - hot weather further north than normal and cold weather further south than normal.

But as well as meandering more, the jet stream is also tending to get stuck in so-called 'blocking patterns', where, instead of moving gradually eastwards, the jet stream wave peak or wave trough stays in much the same place for months.  This blocking may be due to stationary highs over land mass and lows over ocean, with the jet stream weaving round them.  Here we may be a witnessing of a dynamic interaction between the effects of Arctic amplification and global warming.

Note that there was a similar dynamic interaction in the case of Sandy.  Ocean surface warmed by global warming lent strength to the hurricane and provided a northerly storm track up the coast; and then a sharp left turn over New York was prompted by meeting a jet stream blocking pattern.

As a climate scientist, one might have expected a reduced gradient between tropics and pole to have some effect on weather systems, because there is less energy to drive them.  The normal pattern comprises 3 bands of weather systems around the planet for each hemisphere, with each band having 'cells' of circulating air.  The air rises at the tropics, falls at the next boundary, rises at the next, and falls at the pole.  There has to be an odd number of bands, so that there is air rising at the equator and falling at the poles.  The jet streams are at the boundary between the bands.

As the temperature gradient between tropics and pole reduces, one would expect the weather systems to spread in a chaotic manner, meandering more wildly.  This is exactly what has been observed.

The sticking of the jet stream must be associated with non-uniformities of surface topology and heat distribution.  Thus highs and/or lows are getting stuck over some feature or other, while the jet stream meanders around them.

Thus there is a reasonable explanation for how we are getting weather extremes, simply as a result of a reduced temperature gradient between Arctic and tropics.   Another argument that has been given, most notably by Professor Hansen, is that the extreme weather events are simply a result of global warming - i.e. a general rise in temperature over the whole surface of the planet.  Global warming can indeed explain a gradual increase in the average intensity of storms (whose energy is derived from sea surface warming) and in the peaks of temperature for heat waves.  But global warming does not explain the observed meandering of the jet stream and associated weather extremes, both hot/dry and cold/wet, whereas the warming of the Arctic can explain these observations.  Furthermore the non-linear warming of the Arctic can explain the non-linear increase of extreme events.

Since this hypothesis seems reasonable, it is fitting that the precautionary principle should be applied when it comes to trends.  The forecasting of extreme events must take into account the trend towards more extreme events as the Arctic warms.  And the Arctic is liable to be warm about twice as fast in 2015 as it in 2012, because of sea ice retreat.

This all adds up to a picture of abrupt climate change in the Arctic, now spreading to the Northern Hemisphere and soon to afflict the whole planet.  These changes must be halted and then reversed.  Meanwhile the effect on food security must be handled before the whole situation gets much worse.

Handling the food crisis

What should a country do, when faced by such a grave food crisis?  The immediate response may be to become introspective and try and insulate the country from what is happening in the rest of the world.  For a country like the UK, this is difficult, because of importing 40% of food and much of its energy requirements, such as natural gas from Kuwait.  For the US, self-sufficiency has been a goal for energy, but there is a food problem from weather extremes, which particularly seem to affect the country.

For countries which have been net exporters of basic foodstuffs, the response may be to halt exports, as Russia did for wheat recently to protect its citizens but pushing up the food price index in the process.  If this type of response is widespread, then a vicious cycle of food price increase and protectionism could develop, with a stifling of world trade and an increase in strife between countries.

But what people must not do is to ignore the non-linear trends and blame the weather extremes either on random fluctuations or on essentially linear effects such as global warming.  The danger is that governments will do nothing at all to address the underlying cause of the linearity, which lies in the vicious cycle of Arctic warming and sea ice retreat.

We believe that a sensible strategy is two-fold: to deal with the symptoms of the disease and the cause of the disease.

The most conspicuous symptoms are floods, droughts, food price increase, security of food supply and food shortages.  Less conspicuous are the effects of food price increase on global unrest and the spread of disease among humans, animals and plants.  Water shortages may also be a growing issue in many countries. The changing frequency, severity, path and predictability of tropical storms (hurricanes, typhoons, monsoons, etc) will be a major issue for many countries, especially those with large coastal conurbations and those who depend on regular monsoons. Coastal regions and cities that have hitherto been immune to such storms may suffer great damage, as happened with Sandy to New York and could happen to Dubai.

Countries which rely heavily on one crop for income are liable to be heavily hit by weather changes.

By studying trends, one can estimate how quickly the situation is likely to deteriorate.  One can see an exponential rise in extreme weather events, and the food price index is liable to follow this trend because of reduced agricultural productivity.

The price of food is dependent on a number of factors besides agricultural productivity, and these are under human control.

The policy of “food for fuel” has undoubtedly driven up the price of food, so this policy needs to be changed.  Biofuel can still be part of policy, but must come from sustainable sources and without competing with food. For example biofuel from the biochar process can actually benefit food production, because the residue from heating biomass and producing the biofuel is a form of charcoal that can be used for improving soils, water retention, and crop yields.

An important factor in the price of food is the price of oil, because of use of oil in agriculture, not only for farm machinery and food transport but also for artificial fertiliser.   Unfortunately much oil comes from countries where much of the population is on the bread line, so the social unrest from food price increase can shut down access to the oil which further pushes up the cost of food in a vicious cycle.

Speculation on the price of oil can be a major factor in producing spikes in the food price index, so this needs to be discouraged in some way.  Similarly speculation on food commodities needs to be discouraged.

Perhaps the most important factor is management of food stocks, seed stocks, planting practice (use of monoculture, GM crops, etc.), timing of planting and irrigation.  The timing becomes increasingly problematic as global weirding increases and weather becomes more unpredictable.  There needs to be advice to farmers on how to cope – e.g. by judicious diversification and reduced reliance on single crop planting.

Cooling the Arctic

Dealing with the underlying cause of the climate extremes turns out to be even more important than dealing with the consequences on food security, because the underlying cause is a process which is gaining momentum and could become unstoppable in 2013.

In effect, we are approaching a point of no return, after which it will be impossible to rescue the situation.

The speed of action is required because of the speed of sea ice retreat.  All indications are that there will be a major collapse of sea ice next year, with a new record minimum.  And September 2015 is likely to be virtually sea ice free.

This is the inescapable evidence from the PIOMAS sea ice volume data.

Even if there were no danger from passing a point of no return, rapid action would be worthwhile because of the financial and human cost of the abrupt climate change.

The only chance of halting this abrupt climate change in its tracks is to cool the Arctic, and prevent Arctic amplification disrupting the jet stream more than it is at the moment.  Delay to such action would cost around a trillion dollars per year and put a billion people into starvation.


Figure 3 ~ The trend analysis of PIOMAS data

The target should be to prevent a new record low of sea ice extent next year (2013).  This involves providing sufficient cooling power into the Arctic to offset the warming which has built up as the sea ice has retreated.  This warming is due to the “albedo flip effect” and is estimated as being up to 0.4 petawatts averaged over the year.  This warming has to be countered by an equal cooling power, if the target is to be met.

This is a colossal engineering and logistics challenge.  A war effort on developing, testing and deploying geoengineering techniques would be justified to meet the target.

Cloud effects that could be exploited to cool the Arctic

Clouds have effects in opposite directions: reflecting sunshine back into space and reflecting thermal radiation back to Earth.  The former cools, the latter heats.  Geoengineering tries to enhance the former and/or diminish the latter, to alter the balance towards cooling.  The balance is critically dependent on the droplet size: there is an optimum size for reflecting sunlight, as for the particles to make white paint.  Particles much larger than this will reflect thermal radiation strongly.

When the sun is high in the sky, the balance is towards cooling by reflection of sunlight; but when the sun is low in the sky, the balance is towards heating by reflection of thermal radiation.  Thus techniques for cloud brightening tend not to work well in winter at high latitudes.  

Clouds also can produce snow which will generally increase albedo to around 0.85 where it falls; whereas rain will generally reduce albedo by melting any snow and by forming puddles or pools on land or ice surfaces.  However, rain or snow falling through a dusty atmosphere can darken the surface on which it falls.  Hence the black carbon from tundra fires may have some sunshine reflecting effect while in the atmosphere, but then reduce albedo when it’s washed out.

There are a number of different things to do with clouds: create them (typically as a haze), brighten them, extend their life, reduce them by precipitation (rain or snow), or reduce them by evaporation.  

Perhaps the simplest form of geoengineering is to create a haze.  Particles or fine droplets of haze in the troposphere tend to get washed out of the air within days or weeks, whereas if they are in the stratosphere they can last for months or even a few years, depending on their initial altitude and latitude.  The stratosphere Brewer-Dobson meridional circulation has air slowly moving in an arc from lower latitudes to higher latitudes, see http://en.wikipedia.org/wiki/Brewer-Dobson_circulation

By judicial choice of quantity, altitude and latitude for injection of aerosols, one can obtain a much longer cooling effect in the stratosphere than in the troposphere. Thus one needs much less aerosol in the stratosphere to produce the equivalent effect in the troposphere.  Note that the eruption of Mount Pinatubo in 1991 produced a global cooling of 0.5 degrees C over a period of two years.

Providing cloud condensation nuclei (CNN) of the right size can brighten clouds without significantly affecting their lifetime. Sulphate aerosol in the troposphere produce both a reflective haze and CNN. These combined effects from aerosol ‘pollution’ have masked global warming by as much as 75%.  If all coal-fired power stations were shut down, there would be a significant decrease in aerosol cooling and an upward leap in the rate of global warming.

Three preferred cooling techniques

A combination of three cooling techniques is proposed, to give flexibility in deployment and maximise the chances of success:
  • stratospheric aerosols to reflect sunlight;
  • cloud brightening to reflect more sunlight;
  • cloud removal to allow thermal radiation into space.

The first technique mimics the action of large volcanoes such as Mt Pinatubo which erupted in 1991 and had a cooling effect of 0.5 degrees C over 2 years due to the sulphate aerosols it produced in the stratosphere.  However larger particles in the aerosol are liable to reflect thermal radiation from the planet surface, hence having a warming effect.  To avoid this, there is an advantage in using TiO2 particles, as used in white paint.  These can be engineered to a constant size, and coated to produce required properties, such as not sticking to one another. Large quantities could be dispersed at high latitudes in the lower stratosphere either using stratotankers or balloons, to have an effect lasting a few months during spring, summer and early autumn.  Due to circulating winds, the aerosol will spread around the latitude where it has been injected.

Cloud brightening is a technique whereby a very fine salt spray is produced from special spray nozzles mounted on a ship, and gets wafted up to clouds where it increases their reflective power.  Whereas stratospheric particles can provide blanket cooling at particular latitudes, the brightening technique can be used to cool particular locations, using sophisticated modelling to decide when and where is best to do the spraying.

The third cooling techniques involves removing certain high clouds during the months of little or no sunshine when they are having a net blanketing effect – reflecting heat back to the ground.

Additional techniques should be considered for more local cooling, especially by increasing surface albedo; for example one could increase snowfall over land or brighten water by injection of tiny bubbles. Another technique is to break up the sea ice in autumn and winter, which has the effect of thickening the ice and producing what looks like multi-year ice.  A very promising approach is to reduce currents carrying water into the Arctic Ocean, in particular the partial damming of the Bering Strait.

Note that all the above techniques are expected to enhance the Arctic ecosystem, which is in danger of sharp decline as a result of sea ice collapse.

Local measures to save the sea ice

There are a number of physical ways to reduce loss of sea ice:
  • corral the ice when it is liable to break up and float into warmer waters
  • reduce wave action at the edges
  • replace or cool warmer surface water using colder water from beneath
  • thicken the ice by shoving ice on the water onto other ice
  • thicken the ice by adding water on top to freeze
  • thicken the ice by adding snow (which may also brighten it)
  • add a layer of white granules or reflecting sheet.

The last of these can also be used for retaining snow.  It could be used on the Greenland Ice Sheet to preserve snow and ice.  (AMEG founder member, Professor Peter Wadhams, has co-authored a paper on the subject, to be presented at AGU.  He has also done work on how tabular icebergs break off at the edges.)

Pulling out all the stops, whatever

There is one thing that we do know can produce an appropriate amount of cooling power: the sulphate aerosol in the troposphere, as emitted from coal-fired power stations and from ship bunker fuel.  This aerosol has offset CO2 warming by around 75% in the past century.  There should be a temporary suspension of initiatives and regulations to suppress these emissions, while they are having a significant cooling effect in the Northern Hemisphere, unless human health is at risk.

Much attention should be given to short-lived climate forcing agents, such as methane.  There should be a moratorium on drilling in the Arctic, as proposed by the UK Environment Audit Committee in their report “Protecting the Arctic”, September 2012.

Measures to reduce black carbon should be taken.  There should be teams of fire-fighters set up to take prompt action on tundra fires, which produce black carbon, methane and carbon monoxide – all undesirable.

More direct means to deal with weather anomalies

Cloud brightening and wave pump technology can be used to cool the surface of the sea in specific areas.  This technology holds promise to reduce the power of hurricanes and other storms, but might also be used to produce precipitation where needed or dampen oscillations of the planet’s climate system, e.g. ENSO (El Nino Southern Oscillation).

More direct means to deal with methane emissions

AMEG realises that there is a problem of growing methane emissions from the high latitude wetlands and from permafrost which is thawing, both on land and under the sea bed.  Methane is a potent greenhouse gas, so we have been investigating how to suppress methane and methane production.  We have some valuable ideas, based on use of diatoms in water treatment.  The water treatment means that fish can thrive where previously the water was brackish.  Thus, not only is methane suppressed, but fish farming becomes possible on a very large scale at very low cost.   Increasing food production is going to become paramount in a warming world with a growing population.

Modelling and monitoring

Essential to all geoengineering deployment is good modelling of the climate system. Unfortunately, none of the global climate models deal with the speed of events in the Arctic.  It is essential to have a good understanding of the processes at work.  Part of the war effort to meet the geoengineering target must be devoted to improving the models.

Similarly there must be adequate monitoring facilities to ascertain the effects of geoengineering, and prevent inadvertent negative impacts.  Some satellites which could supply appropriate monitoring are nearing the end of life or coming out of service, so must be replaced as quickly as possible.

Not an end to the story

Cooling the Arctic is not the only step that is required to save civilisation from fatal consequences of mankind’s interference with the Earth System, but it is prerequisite.  Assuming the sea ice is restored, global temperatures could still rise too high, oceans acidify too much or rainforests dry out and burn down.  AMEG supports efforts to deal with such matters.

But cooling the Arctic is the first emergency response strategy.


ACTION PLAN

This is in two parts: firstly interventions for adjustment/restoration/repair of critical Earth System components, especially in the Arctic; and secondly the food crisis, especially the  politics of dealing with the situation such to avoid vicious cycles that could jeopardise stability of food production or lead to panic among peoples.

Something akin to a war room needs to be set up, bring experts from all the relevant fields, in order to brainstorm on the problems and possible ways forward.

Interventions in the Earth System

These interventions can be viewed as adjustments, restoration and repair of critical Earth System components.  Examples include cooling the Arctic, restoring the sea ice and returning polar jet stream behaviour to a more acceptable mode.

For each intervention there may need to be modelling to predict effects and effectiveness and to anticipate problems arising. Correspondingly there needs to be observations, monitoring and measuring of results.  The observation of process and the measurement data obtained should be fed back into the models to improve them.

As for appropriate interventions, there are a number of things to do immediately in parallel:

  1. Consider practices and regulations that are having, or risk having, a heating effect on the Arctic.  A postponement of drilling in the Arctic would be sensible, because of inevitable escape of methane but also because of the risk of blowout with or without oil spill. 
  2. Try to maintain or even enhance the current cooling effect from currently emitted sulphate aerosols in the troposphere at mid to high northern latitudes.  For example the regulation to ban bunker fuel for ships should be relaxed while encouraging continued use of bunker fuel where the resulting aerosol emissions might be beneficial.  Reduction of sulphate aerosol ‘pollution’ will be unpopular with many environment groups, but the priority to cool the Arctic has to be established.
  3. Establish the positive and negative net forcing from contrails, and encourage flight paths of commercial airplanes to reduce positive or increase negative net forcing.  The ban on polar flights, lifted recently, should be reintroduced.
  4. Reduce black carbon into Arctic.  Make for preparedness to fight tundra fires in Arctic and sub-Arctic. 
  5. Find ways to remove black carbon from coal fired power stations, while allowing or compensating for the cooling effect that their aerosol emissions would be producing without the scrubbing out of sulphur compounds.

Geoengineering actions for enhancing the reflection of sunlight back into space and for increasing the thermal energy emitted into space.

  1. Prepare the supply and logistics for spraying aerosol precursor in large quantities, preferably into the lower stratosphere, for deployment by next March or April (not sooner because the risk of ozone depletion).  Of course, possible negative impacts have to be considered before large scale deployment, but it is worth being fully prepared for such deployment on the assumption that this technique can be made to work effectively.
  2. Develop and test the deployment of suitably reflective particles, of such materials as TiO2, as alternative or supplement to sulphate aerosol.  Prepare for large scale deployment.   
  3. Finance the development of, and deployment capability for, marine cloud brightening, with a view to deployment on a large scale in spring 2013 - assuming that is the earliest conceivable time.  The main technical problem seems to be with the jets, so experts from major companies in the ink-jet technology field need to be brought in.  Boats and land installations need to be kitted out.
  4. Finance the development and deployment capability for cirrus cloud removal, since this is a promising technique.  Suitable chemicals need to be identified/confirmed, with stock-piling of these cloud seeding chemicals.  Aircraft need to be kitted out to spray these chemicals.
  5. Finance brainstorming sessions for geoengineering, with top scientists and engineers, such as to suggest further measures, improvements to above techniques and the development of other intervention ideas.
  6. Finance the research and trials of all promising techniques for helping to cool the Arctic, including the three geoengineering techniques above.  Update Earth System models to deal with the actualities of sea ice retreat, such that the effects of different techniques can be modelled and optimum joint deployment strategies established.

Measures to reduce more specific risks from Arctic warming:

  1. Finance the research and trials of promising techniques for dealing with methane, especially the reduction of methane from wetlands draining into the Arctic.  Use of diatoms to promote methanotrophs (and healthy conditions for fish) is one such technique.
  2. Finance the research and trials of promising techniques for dealing with surface melt of the Greenland Ice Sheet (GIS) and for reducing the speed of ice mass discharge.  The latter is accelerated by warm water at the sea termination of glaciers; therefore consideration should be given to techniques to cool this water.
  3. Consider techniques for reducing Arctic storms and their strength.  Techniques should be developed for reducing the frequency and severity of tropical storms, such as to minimise damage, especially to agriculture and low-lying conurbations.
  4. Consider techniques for un-sticking of blocked weather patterns.
  5. Consider techniques for improving surface albedo of sea, lakes, snow and ice by brightening water with bubbles, covering snow and ice with white granules or sheets to prolong albedo, draining pools on ice, forming ice on pools, depositing snow on ice (as fresh snow has a higher albedo) and on land, discouraging growth of plants with low albedo, etc.  

Note that a new idea for improving surface albedo has been suggested in a paper to the AGU 2012, supported by AMEG founder member, Peter Wadhams..  His research on iceberg calving has led to ideas for reducing discharge of ice from the GIS.

A word of warning about finance of research, development and field trials: it is important that the results of such activities are independent, unbiased and free from financial interest.

Food security actions

Immediate actions to be initiated:

  1. Overall there is an immediate requirement for all major governments to establish an emergency ‘watchdog’ committee for internal and world food security issues. This committee should have direct access to the leadership of individual nations and include their UN Ambassador. The associated costs, in terms of humanitarian impacts alone, should warrant this move. When the assessed cost of the potentially associated national economic factors are weighed, there should be little disagreement regarding the necessity for establishing this ‘watchdog’ committee.
  2. The US Renewable Fuels Standard (“RFS”), a provision of the US Energy Policy Act of 2005, should be evaluated for a temporary stay. Depending entirely on the US corn harvest, this could transfer between 4 to 5 billion bushels back to the food market. That would reduce upward price pressure in the cereals markets and further assist by suppressing speculation in that area of food commodities.
  3. The European Renewable Energy Directive 2009/28/EC should similarly be reviewed and measures put in place to temporarily divert all relevant crops from the fuel to the food market.
  4. In both cases outlined in points 3 & 4 the emphasis should be on ‘temporary emergency measures’ and should only be applicable to crops that can be diverted to the food chain.
  5. A general directive should be agreed between all nations at the UN to prohibit the sale of OTC derivatives, in any nation, by any ‘seller’, that have any content relative to food commodities. This action will assist in dissuading institutional investors speculating in food commodities.
  6. If the crisis deepens point 4 should be further reinforced by prohibiting futures contracts in food commodities being sold to any entity who will not take actual delivery of the contracted goods. Great care will be necessary with this proposal as it is known that hedge funds, and investment banks, have established warehousing to control certain commodity pricing. Typical examples are the attempted 2010 cornering of the world cocoa market by a UK hedge fund and the current Goldman Sachs control of the US aluminium market.
  7. An alternative international seed bank must be created to provide seeds for subsistence farmers; ones that are devoid of the ‘terminator’ gene. In periods of high crop failure the inability to harvest seeds for the coming year has a crippling impact on subsistence farmers. Note that it is estimated 160,000 Indian farmers alone have committed suicide since 1967 due in part to this situation.

Following the launch of AMEG’s ‘Strategic Plan’ the above actions will be communicated to all world leaders and relevant parties in the form of an ‘Essential Action Plan’ to match the pending circumstances of the change in the world’s weather patterns.

For further details, see the website of the Arctic Methane Emergency Group at
AMEG.me or contact AMEG Chair John Nissen at: johnnissen2003@gmail.com

Wednesday, December 5, 2012

Arctic anomalies linked to extreme weather

Surface temperature anomalies of 20 degrees Celsius are not uncommon in the Arctic these days. The image below shows surface temperature anomalies on November 9 and 10, 2012.


Paul Beckwith, regular contributor to this blog, comments as follows on the conditions in the Arctic:
“The Arctic meteorology is unprecedented at the moment. Huge ridges of high pressure are crossing the Arctic ocean cutting off the Siberian cold region from the North American region. Very little cold air is present in the entire system, and it is exhibiting very bizzare fragmentation. Nothing like a “normal” polar vortex is apparent.

The ridge could just be due to this greatly reduced volume of cold air, but I suspect there is much more to the situation then that. It seems that there must be some source of heat to create this ridge. Could be warm air rising up from open water regions in the Arctic, however most of the warm water is now isolated from the atmosphere by the sea ice.

It seems more likely to me that the high levels of methane with GWP > 150 or higher are causing higher long-wave absorption and heating in these regions, but I have not seen methane concentration distributions over the Arctic from AIRS satellites lately.”
So, let's have a look at the methane levels for those days. The image below shows the methane levels for the above two days.


Paul continues:
“This is what abrupt climate change looks like. In the paleorecords global average temperatures increased over 6 degrees C within a decade or two, I suppose we will know more precise numbers in a few short years.”

Paul repeats the prediction he made back in June in this the post When the sea ice is gone
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!

Meanwhile, extreme weather continues to strike areas outside the Arctic. In the U.K, airports were closed due to snow, following a period of heavy rainfall in November.

In Russia, extreme weather caused a huge traffic jam; see the BBC reports here and here, prompting Veli Albert Kallio, also one of this blog's contributors, to make the following comments:
Veli Albert Kallio in front of Peter Wadhams and John Nissen at
APPCCG event, March 13, 2012, House of Commons, London
“The Ewing-Dunn Precipitation (the lake-effect snow) from warmed-up Arctic Ocean has taken the Russian Government's winter preparations by suprise of its severity, with the Russian Government minister banging his fist as standing queues of vehicles reoccurs and is now 190 kilometres (120 miles) long between the capital Moscow and St. Petersburg.

I have been warning from the leaked files since July at this and other groups that December 2012 was going to be like this. We need to tell the Russian Interior Minister who bangs his fist on TV that he should not blame his road officials, but the global warming and loss of sea ice from the Barents and Kara Seas and generally warmed up North Atlantic - Arctic Ocean regions.”

Saturday, December 1, 2012

Aviation Policies

The European Union's policy on Aviation Emissions

From the start of 2012, the European Union (EU) required its members to include emissions from flights arriving at and departing from their airports in the EU scheme of emissions allowances and trading, while encouraging other nations to take equivalent measures. The EU exempts biofuel and claims to take a 'comprehensive approach' to reducing environmental impacts of aviation. To create space for political negotiations to get an international agreement regulating emissions from aviation, the EU has meanwhile postponed implementation of its directive by one year.

What kind of international agreement could be reached on aviation emissions? What policies work best? How do aviation policies fit into a comprehensive approach?

A Comprehensive Plan of Action on Climate Change

A comprehensive plan is best endorsed globally, e.g. through an international agreement building on the Kyoto Protocol and the Montreal Accord. At the same time, the specific policies are best decided and implemented locally, e.g. by insisting that each nation reduces specific emissions by a set annual percentage, and additionally removes a set annual amount of carbon dioxide from the atmosphere and the oceans, followed by sequestration, proportionally to its current emissions.

Policy goals are most effectively achieved when policies are implemented locally and independently, with separate policies each addressing the specific shifts that are each needed to reach agreed targets. Each nation can work out what policies best fit their circumstances, as long as they each independently achieve agreed targets. Counting emissions where they occur will encourage nations to adopt effective policies, such as imposing fees on the sales of products in proportion to the emissions they cause, and adopting product standards that ban products that would otherwise cause unacceptably high emissions while clean alternatives are readily available.


Clean Energy Policies

Policies aiming to achieve a shift to clean energy will apply to many sectors such as transportation (including aviation), power plants, and industry and buildings which are also large consumers of fossil fuel. The above image also shows policies specifically targeting aviation, in addition to clean energy policies that apply across sectors.

The image below proposes feebates as the most effective way to accomplish the necessary shift to clean energy. In such feebates, fees are imposed on polluting energy and associated facilities, with revenues used - preferably locally - to fund rebates on clean energy and associated facilities.


In line with such feebates, each nation could impose fees on jetfuel, while using the revenues for a variety of purposes, preferably local clean energy programs. Where an airplane lands arriving from a nation that has failed to add sufficient fees, the nation where the airplane lands could impose supplementary fees. Such supplementary fees should be allowed under international trade rules, specifically if revenues are used to fund direct air capture of carbon dioxide.

Aviation Policies

As said, apart from clean energy policies, it makes sense to additionally implement policies specifically targeting aviation. Airplanes not only cause carbon dioxide emissions, but also cause other emissions such as black carbon and NOx, contrails and cirrus cloud effects. The EU emissions scheme only targets a limited set of emissions, while also looking at their global warming potential, rather than the potential of emissions to cause warming locally, specifically in the Arctic. A joint 2011 UNEP/WMO report mentioned many measures to reduce black carbon and tropospheric ozone, adding that their implementation could reduce warming in the Arctic in the next 30 years by about two-thirds.

A 2012 study by Jacobson et al. concludes that cross-polar flights by international aviation is the most abundant direct source of black carbon and other climate-relevant pollutants over the Arctic. Rerouting cross-polar flights to instead circumnavigate the Arctic Circle therefore makes sense. While such rerouting consumes more fuel, it could reduce fuel use and emissions within the Arctic Circle by 83% and delay pollutant transport to the Arctic.

Given the need to act on warming in the Arctic, it makes sense to ban cross-polar flights. To further reduce the flow of pollutants to the Arctic caused by aviation, it makes sense to add fees on all jet flights. Such fees on jet flights would be additional to the above fees on fuel. This could further facilitate a shift from aviation toward cleaner forms of transportation, such as high speed rail. Where the revenues of such fees are used to fund direct air capture, they could also help kickstart an industry that could produce synthetic jetfuel and that could be instrumental in bringing atmospheric levels of carbon dioxide back to 280ppm.

Monday, November 26, 2012

Climate management will be the key to massively improving renewable energy performance and the eradication of poverty

By Bru Pearce

Bru Pearce,  AMEG member
who works at Envisionation Ltd
Climate management is going to be essential to improve the efficiency and cost of renewable energy and enable rapid decarbonisation of world’s energy generation systems to avoid catastrophic climate change. Ultimately control of our regional weather will be the solution to our greatest problems.

In a previous post ‘Geo engineering after the auto pilot has been turned off ‘ I concluded with the statement, “The time is coming to embrace geo-engineering, (after all we already have 4 billion years of experience in it behind us!).”

I was making the point that primeval life began changing our planets climate almost from its very first existence and that man as a recent incarnation in evolution has been significantly effecting the climate since we first hunted species to extinction and started cutting down huge swaths of forest to convert to agricultural lands.

Of course none of mans early efforts at geoengineering compare to the colossal scale of our latest experiment: that of practically doubling atmospheric CO2 in the last 200 years. 75% of which has been emitted in the last 50 years, in line with our spectacular population growth.

I spent the weekend of 3rd November at the Arctic Methane Emergency Group’s workshop on ‘how to cool the Arctic’ with the objective of retaining the sea ice in order to prevent massive methane release and in the hope of re-stabilising the jet stream. (It is the Jet Stream that in the last few years has become increasingly convoluted and led to the extremes of weather now being experienced in the Northern Hemisphere).

The premise of this meeting was that we do not have the time or the capability to implement a switch to an all renewable energy paradigm and that even if we did cut out our CO2 emissions entirely, at 400 ppm we have already set the planet up for 3 to 4 C° of warming.

Methane hydrates from the defrosting Arctic sea beds are already beginning to enter the atmosphere which will trigger numerous other feedback loops and lead to runaway global warming. Therefore we are going to have to take emergency measures and actively cool the Arctic in order to buy time in which to stabilise and decarbonise the atmosphere.

A truly dire situation, but the encouraging part about the meeting was that it would appear that the necessary technologies to manage our climate are within our grasp.

Many people shudder at the thought of engineering our climate, but given that we have, initially unwittingly but now knowingly, engineered our way deeper into the situation, we should not be surprised at the need to engineer a correction.

So I got to thinking about what climate management could do for us?

Here’s my list:
  • Massively improve the efficiency of our renewable engineering capabilities by:
    - Ensuring consistent winds
    – leading to greatly improved wind farm efficiency- Ensuring clear skies and massively upping the efficiency of photovoltaic’s as well as allowing radiated heat to escape into space at night 
  • Produce predictable rainfall, not just the amount, but when and where. This can open up many more hydroelectric power opportunities 
  • Increase agricultural output, for food and for biofuels 
  • Deliver water to all populations 
  • Provide perfect weather for tourism resorts, sunny days and snow in ski resorts 
  • Greening deserts opening up new agricultural land, (much better than cutting down forests for agriculture) 
  • Protect and preserve forests from drought 
  • All of the above collectively leading to the eradication of poverty 
In fact the more I think on it, the more obvious it is that humanity is going to have to take control of our climate. Firstly to avoid catastrophe and secondly to ensure that the all-renewable energy economy can become a reality, capable of supporting the power needs of 9 billion people, to the same modern standards that we all wish to achieve. It is essential to achieve this without destroying what is left of our natural environment and genetic diversity.

Ok it sounds utopian, but it is the future we want, the alternative is an unimaginable horror story. We are capable to of achieving great things; why on Earth would we not?

So how do we get there?

We are going to have to establish some very clear international rules:
  • A target to reduce and maintain CO2 at 280ppm as per the last 12,000 of the Holocene, (with further small corrective increases as necessary over time to prevent the decline into the next ice age) 
  • Sea level to be maintained at current levels 
  • Ice and snow extent to stay within the norms of the 20th century averages 
  • Systems will have to be put in place to manage microclimate change with planning proposals and applications over any changes in river water volume. And special applications will have to be made for desert recovery. With detailed studies into knock on impacts on other areas. 
  • Key features of natural cycles will have to be retained, but this does not mean that hurricanes, forest fires, floods and drought cannot be managed. 
Actions

It should be possible to ensure that most rain falls in the morning and evenings, while still maintaining the continuity of seasonal changes.

Being able to control the weather means knowing the weather in advance and being able to rely on it. Trade winds blowing consistently will make it possible to power ships by sail and for windmills to turn constantly.

It will be even more important for countries that are maintaining rain forests and other large areas of the climate management biosphere, to be compensated by the industrialised and agriculturalised parts of the world for the services they provide. Those services will need to be measured and brought into the dynamics of the new global economy.

In order to take control of our climate we first need to fully understand it. This means that our current efforts to monitor the biosphere need to be massively upgraded. Monitoring systems across the ocean surfaces and depths, on land and in the atmosphere, need to be installed to fully cover the planet. So that every small change can be recorded and its impacts identified.

An appropriate scale might be something like a one for every 100km2. With the data made available to a number of separate super computers that can give us a full evaluation of how the earth systems work. Of necessity this will require integrating the operation of the world economy, crop production, population and all other human dynamics. A huge undertaking that needs to be mans greatest and most urgent endeavour. (For more on this take a look at the International Centre for Earth Simulation foundation web site http://www.icesfoundation.org)

Total management of Earth’s climate will take time. It is something to work towards, although we may have to take emergency measures to cool the Arctic very soon. Small scale tests and research should begin immediately and be given all the funding necessary, so that we can meet the emergency and quickly deliver a fully renewable energy economy.

Learning to engineer our climate holds great promises for all life on earth and can make the dream of an all-clean energy future come true. I believe we can and have to do this.