High methane levels over the Arctic Ocean on February 17, 2014

Above image shows IASI methane readings over the last day or so, when levels as high as 2223 ppb were recorded.

Where does the methane come from?

On above image, methane shows up prominently along the faultline that crosses the Arctic Ocean from the northern tip of Greenland to the Laptev Sea. This indicates that the methane originated from the depths of the Arctic Ocean, where sediments contain large amounts of methane in the form of free gas and hydrates, which have become destabilized.

High methane concentrations have persistently shown up over the Arctic Ocean since October 1, 2013. On January 19, 2014, levels as high as 2363 ppb were recorded over the Arctic Ocean, as illustrated by the image below, from an earlier post.

[ from earlier post, click on image to enlarge ]

Below is a comparison of methane readings for the week from February 9 to 16, 2014, compared to the same period in 2013.

[ from earlier post, click on image to enlarge ]

The above comparison shows that there is a lot of methane over the Arctic Ocean that wasn't there last year. 

Furthermore, high methane readings show up where currents move the sea ice out of the Arctic Ocean, in areas such as Baffin Bay. This indicates that methane that is released from the seafloor of the Arctic Ocean appears to be moving underneath the ice along with exit currents and entering the atmosphere where the sea ice is fractured or thin enough to allow the methane to pass through. 

Also note that more orange areas show up on the southern hemisphere in 2014, indicating that more methane from the northern hemisphere is now spreading south beyond the equator. This in addition to indications that more methane is rising and building up at higher altitudes, as discussed in an earlier post.

Causes

What made these high releases from the seafloor of the Arctic Ocean persist for so long? At this time of year, one might have thought that the water in the Arctic Ocean would be much colder than it was, say, on October 1, 2013.

Actually, as the combination image below shows, sea surface temperatures have not fallen much at the center of the Arctic Ocean between early October, 2013 (left) and February 17, 2014 (right). In the area where these high methane concentrations occured, sea surface temperatures have remained the same, at about zero degrees Celsius.

[ click on image to enlarge ]

The above comparison image shows that, while surface temperatures in the Atlantic Ocean may have fallen strongly with the change of seasons, surface temperatures in the Arctic Ocean have changed only little.

In this case of course, what matters more than surface temperatures are water temperatures at greater depth. Yet, even here temperatures in the Arctic Ocean will have decreased only slightly (if at all) compared to early October 2013, since the Gulf Stream has continued to push warmer water into the Arctic, i.e. water warmer than the water in the Arctic Ocean, so the heating impact of the Gulf Stream continues. Also, sea surface temperature anomalies along the path of the Gulf Stream continue to be anomalously high, as the image below shows.

The situation looks even more grim on the Climate Reanalyzer image below, showing sea surface temperature anomalies that are far more profound in the Arctic Ocean.

Note also that, as the sea ice extent increased, there have been less opportunities for the heat to evaporate on the surface and for heat to be transferred from the Arctic Ocean to the air.

Finally, what matters a lot is salinity. The combination image below compares salinity levels between October 1, 2013 (left), and February 17, 2014 (right).

[ click on image to enlarge ]

Salinity levels were low on October 1, 2013, as a lot of ice and snow had melted in the northern summer and rivers had carried a lot of fresh water into the Arctic Ocean. After October 1, 2013, little or no melting took place, yet the Gulf Stream continued to carry waters with higher salt levels from the Atlantic Ocean into the Arctic Ocean.

Annual mean sea surface salinity

Seawater typically has a salinity level of over 3%; it freezes and melts at about −2°C (28°F). Where more saline water from the Atlantic Ocean flows into the Arctic Ocean, the water in the Arctic Ocean becomes more saline. The freezing and melting point of fresh water (i.e. zero salinity) is 0°C (or 32°F). More salinity makes frozen water more prone to melting, i.e. at temperatures lower than 0°C, or as low as −2°C.

As the salinity levels of the water on the seafloor of the Arctic Ocean increased, the ice that had until then held the methane captive in hydrates on the seafloor of the Arctic Ocean started to melt. Indeed, the areas in the Arctic Ocean where the high methane releases occurred on January 14, 2014 (top image) show several practical salinity units (psu) increase since October 1, 2013.

Higher salinity levels are showing up closer to the faultline that runs through the Arctic Ocean from the top of Greenland to the Laptev Sea.


Quantities

These high levels of methane showing up over the Arctic Ocean constitute only part of the methane that did escape from the seafloor of the Arctic Ocean. Where these high concentrations did show up, the ocean can be thousands of meters deep, giving microbes plenty of opportunity to decompose methane rising through the water first. Furthermore, the methane has to pass through sea ice that is now getting more than one meter thick in the area where these high levels of methane showed up on satellite records. In conclusion, the quantities of methane that were actually released from the seafloor must have been huge.

Importantly, these are not one-off releases, such as could be the case when hydrates get destabilized by an earthquake. As the Arctic-news blog has documented, high releases from the seafloor of the Arctic Ocean have been showing up persistently since early October 2013, i.e. 4½ months ago. This blog has warned about the threat for years. This blog has also described in detail the mechanisms that are causing these releases and the unfolding climate catastrophe that looks set to become more devastating every year. The poster below illustrates the danger.

[ click on image to enlarge - note that this is a 4.9 MB file that may take some time to fully load ]

Impacts and Response

Huge releases from the seafloor of the Arctic Ocean have occurred persistently since early October 2013, even when releases like this may show up for one day in one area without showing up in that same area the next day on satellite images.

This apparent 'disappearance' can be due to the Coriolis effect that appears to move the methane, whereas it is in fact the Earth that is spinning underneath the methane. This doesn't mean that the methane had disappeared. Actually, much of this methane will persist over the Arctic for many years to come and will continue to exercize its very high initial warming potential over the Arctic for years.

Furthermore, even if less methane may show up on satellite images the next day, that doesn't necessarily mean that releases from the seafloor has stopped. Instead, it looks like methane is being released continuously from destabilizing hydrates. The methane may accumulate underneath the sea ice for some time, to burst through at a moment when fractures or ruptures occur in the sea ice, due to changes in wind and wave height.

Methane released from the Arctic Ocean seafloor has contributed to high surface temperature anomalies over the Arctic Ocean in a number of ways. As a potent greenhouse gas, methane is trapping heat that would otherwise radiate into space. Furthermore, methane rising through the sea ice reduces growth of the sea ice.

The danger is that methane will further warm up the air over the Arctic, causing further weakening of the Jet Stream and further extreme weather events, particularly extreme warming of water all the way along the path of the Gulf Stream from the Atlantic Ocean into the Arctic Ocean, in turn triggering further releases from hydrates at the seafloor of the Arctic Ocean and escalating into runaway global warming. This threat calls for comprehensive and effective action, such as described at the ClimatePlan blog.

Post by Sam Carana.

CO2 growth highest on record

Despite many promises, global emissions of carbon dioxide (CO₂) continue to grow.

NOAA figures show that 2013 CO₂ level growth was the highest ever recorded, i.e. 2.95 ppm.

The EPA expects U.S. 2013 energy-related CO₂ emissions to be 2% higher than in 2012.

The UC San Diego image below shows CO₂ levels in the atmosphere over the past two years.

Back in September 2013, John Davies warned: “The world is probably at the start of a Runaway Greenhouse Event which will end most human life on Earth before 2040. This will occur because of a massive and rapid increase in the carbon dioxide concentration in the air which has just accelerated significantly. The increasing Greenhouse Gas concentration, the gases which cause Global Warming, will very soon cause a rapid warming of the global climate and a chaotic climate.”

The post featured a graph with a 4th-order polynomial trendline pointing at some 7.5 ppm CO₂ annual growth by 2040. While many welcomed the warning contained in the graph, some argued against using higher-order polynomial trendlines. So, for those who don't feel comfortable with a 4th-order polynomial trendline, the graph below adds both a linear trendline and a 3rd-order polynomial trendline.

The 3rd-order polynomial trendline, based on the recent data, points at CO₂ annual growth of some 7 ppm by 2040, justifying the warning sounded by the 2013 graph.

And what do the recent data say, when a 4th-order polynomial trendline is applied? As the image below shows, they show an even steeper rise, reaching 7 ppm growth per year as early as 2030.

As many posts at this blog have warned, rapid growth in greenhouse gases and numerous feedbacks are threatening to push Earth into runaway global warming. This calls for comprehensive and effective action to - among other things - reduce atmospheric CO₂ levels back to 280 ppm, as illustrated by the image below and as further discussed at the Climate Plan blog.

Post by Sam Carana.

High methane levels over the Arctic Ocean on January 14, 2014

[ click on image to enlarge - note that 'level' is the peak reading for the respective altitude ]

Above image shows IASI methane levels on January 14, 2014, when levels as high as 2329 ppb were recorded. This raises a number of questions. Did these high methane levels originate from releases from the Arctic Ocean, and if so, how could such high methane releases occur from the seafloor of the Arctic Ocean at this time of year, when temperatures in the northern hemisphere are falling?

Location

Let's first establish where the methane releases occurred that caused these high levels. After all, high methane concentrations are visible at a number of areas, most prominently at three areas, i.e. at the center of the Arctic Ocean, in Baffin Bay and over an area in Asia stretching out from the Taklamakan Desert to the Gobi Desert.

Closer examination, illustrated by the inset, shows that the highest methane levels were recorded in the afternoon, and at altitudes where methane concentrations over these Asian deserts and over Baffin Bay were less prominent, leading to the conclusion that these high methane levels did indeed originate from the seafloor of the Arctic Ocean.

The image below, showing 1950+ ppb readings over the past few days, illustrates the magnitude of the methane concentrations over the Arctic Ocean.

High concentrations persist over the Arctic Ocean

High methane concentrations have persistently shown up over the Arctic Ocean from October 1, 2013, through to January 2014. On January 19, 2014, levels as high as 2363 ppb were recorded over the Arctic Ocean, as illustrated by the image below.

[ click on image to enlarge ]

Causes

What caused these high releases from the seafloor of the Arctic Ocean to persist for so long? At this time of year, one may have thought that the water in the Arctic Ocean would be much colder than it was, say, on October 1, 2013.

Actually, as the combination image below shows, sea surface temperatures have not decreased much at the center of the Arctic Ocean between early October, 2013 (left) and January 14, 2014 (right). In the area where these high methane concentrations occured, sea surface temperatures have remained the same, at about zero degrees Celsius.

[ click on image to enlarge ]

Furthermore, as the above image shows, surface temperatures in the Atlantic Ocean may have fallen dramatically with the change of season, but temperatures in the Arctic Ocean have changed only little.

In this case of course, what matters more than surface temperatures are water temperatures at greater depth. Yet, even here temperatures in the Arctic Ocean will have decreased only slightly since early October 2013, as the Gulf Stream has continued to push warmer water into the Arctic, i.e. water warmer than the water in the Arctic Ocean. In other words, the heating impact of the Gulf Stream has continued.

Furthermore, as the sea ice extent increased, there have been less opportunities for the heat to evaporate on the surface and for heat to be transferred from the Arctic Ocean to the air.

Finally, what matters a lot is salinity. The combination image below compares salinity levels between October 1, 2013 (left), and January 14, 2014 (right).

[ click on image to enlarge ]

Salinity levels were low on October 1, 2013, as a lot of ice and snow had melted in the northern summer and rivers had carried a lot of fresh water into the Arctic Ocean. After October 1, 2013, little or no melting took place, yet the Gulf Stream continued to carry waters with higher salt levels from the Atlantic Ocean into the Arctic Ocean.

Annual mean sea surface salinity

Seawater typically has a salinity level of over 3%; it freezes and melts at about −2°C (28°F). Where more saline water from the Atlantic Ocean flows into the Arctic Ocean, the water in the Arctic Ocean becomes more saline. The freezing and melting point of fresh water (i.e. zero salinity) is 0°C (or 32°F). More salinity makes frozen water more prone to melting, i.e. at temperatures lower than 0°C, or as low as −2°C.

As the salinity levels of the water on the seafloor of the Arctic Ocean increased, the ice that had until then held the methane captive in hydrates on the seafloor of the Arctic Ocean started to melt. Indeed, the areas in the Arctic Ocean where the high methane releases occurred on January 14, 2014 (top image) show several practical salinity units (psu) increase since October 1, 2013.

Higher salinity levels are now reaching the faultline that runs through the Arctic Ocean from the top of Greenland to the Laptev Sea, where major releases are taking place now, as illustrated by the image below, with faultlines added on the insets.

[ click on image to enlarge ]

Above image shows methane levels recorded on the evening of January 16, 2014 (main image). The top left inset shows all methane readings of 1950 ppb and higher on January 15 and 16, 2014, while the bottom left inset shows methane readings of 1950 ppb and higher on January 16, 2014, p.m. only and for seven layers only (from 469 to 586 mb), when levels as high as 2353 ppb were reached (at 469 mb).

Quantities

These high levels of methane showing up over the Arctic Ocean constitute only part of the methane that did escape from the seafloor of the Arctic Ocean. Where these high concentrations did show up, the ocean can be thousands of meters deep, giving microbes plenty of opportunity to decompose methane rising through the water first. Furthermore, the methane has to pass through sea ice that is now getting more than one meter thick in the area where these high levels of methane showed up on satellite records. In conclusion, the quantities of methane that were actually released from the seafloor must have been huge.

Importantly, these are not one-off releases, such as could be the case when hydrates get destabilized by an earthquake. As the Arctic-news blog has documented, high releases from the seafloor of the Arctic Ocean have been showing up persistently since early October 2013, i.e. three months ago. This blog has warned about the threat for years. This blog has also described in detail the mechanisms that are causing these releases and the unfolding climate catastrophe that looks set to become more devastating every year.

Given that a study submitted in April 2013 concluded that 17 Tg annually was escaping from the East Siberian Arctic Shelf alone, given the vast quantity of the releases from hydrates that show up on IASI readings and given the prolonged periods over which releases from hydrates can persist, I put the methane being released from hydrates under the seafloor of the Arctic Ocean in the highest category, rivaling global emissions from fossil fuel, from agriculture and from wetlands. As said, the amounts of methane being released from hydrates will be greater than the methane that actually reaches the atmosphere. To put a figure on the latter, my estimate is that emissions from hydrates and permafrost currently amount to 100 Tg annually, a figure that is growing rapidly. This 100 Tg includes 1 Tg for permafrost, similar to IPCC estimates.

This is vastly more than the IPCC's most recent estimates, which put emissions from hydrates and permafrost at 7 Tg annually, a mere 1% of the total annual methane emissions globally, as illustrated by the image below.

Impacts and Response

Huge releases from the seafloor of the Arctic Ocean have occurred persistently since early October 2013, even when releases like this may show up for one day in one area without showing up in that same area the next day on satellite images.

This apparent 'disappearance' can be due to the Coriolis effect that appears to move the methane, whereas it is in fact the Earth that is spinning underneath the methane. This doesn't mean that the methane had disappeared. Actually, much of this methane will persist over the Arctic for many years to come and will continue to exercize its very high initial warming potential over the Arctic for years.

Furthermore, even if less methane may show up on satellite images the next day, that doesn't necessarily mean that releases from the seafloor has stopped. Instead, it looks like methane is being released continuously from destabilizing hydrates. The methane may accumulate underneath the sea ice for some time, to burst through at a moment when fractures or ruptures occur in the sea ice, due to changes in wind and wave height.

The threat here is that methane will further warm up the air over the Arctic, causing further weakening of the Jet Stream and further extreme weather events, particularly extreme warming of water all the way along the path of the Gulf Stream from the Atlantic Ocean into the Arctic Ocean, in turn triggering further releases from hydrates at the seafloor of the Arctic Ocean and escalating into runaway global warming. This threat calls for comprehensive and effective action, such as described at the ClimatePlan blog.

Post by Sam Carana.

Abrupt Climate Change

What is Abrupt Climate Change?

Abrupt climate change is defined by the IPCC as a large-scale change in the climate system that takes place over a few decades or less, persists (or is anticipated to persist) for at least a few decades, and causes substantial disruptions in human and natural systems.

Examples of components susceptible to such abrupt change are clathrate methane release, tropical and boreal forest dieback, disappearance of summer sea ice in the Arctic Ocean, long-term drought and monsoonal circulation.

Deposits of methane clathrates below the sea floor are susceptible to destabilization via ocean warming.

Anthropogenic warming will very likely lead to enhanced methane emissions from both terrestrial and oceanic clathrates.

Above extracted from:
- Intergovenmental Panel on Climate Change (IPCC), AR5 Workgroup 1, Technical Summary

New Finding Shows Climate Change Can Happen in a Geological Instant

The Paleocene/Eocene thermal maximum (PETM) is a climate shift that occurred 55 million years ago.

James Wright, Rutgers University Research News -
Morgan Schaller, James Wright, and the core sample
that helped them understand what happened
– and how fast it happened – 55 million years ago.

In a new paper in the Proceedings of the National Academy of Sciences, Morgan Schaller and James Wright present their finding that climate change can and did happen abruptly, or in geological terms, instantaneously.

Following a doubling in carbon dioxide levels, the surface of the ocean turned acidic over a period of weeks or months and global temperatures rose by 5 degrees centigrade – all in the space of about 13 years.

“We’ve shown unequivocally what happens when CO2 increases dramatically – as it is now, and as it did 55 million years ago,” James Wright said.

The film below goes into more detail regarding the current situation.

New Film: Last Hours

The film “Last Hours” describes a science-based climate scenario where a tipping point to runaway climate change is triggered by massive releases of frozen methane. Methane, a powerful greenhouse gas, has already started to percolate into the open seas and atmosphere from methane hydrate deposits beneath melting arctic ice, from the warming northern-hemisphere tundra, and from worldwide continental-shelf undersea methane pools.

“Last Hours” is narrated by Thom Hartmann and directed by Leila Conners. Executive Producers are George DiCaprio and Earl Katz.

For more, also watch some of Thom Hartmann’s interviews.

High Methane Levels persist over Arctic Ocean

High methane levels are prominent over the Arctic Ocean, as illustrated by the image below, covering a period from October 3, 2013, 10:54 am to October 7, 2013, 11:53 pm. The fact that methane has not been present elsewhere in such high concentrations over this period indicates that the methane wasn't carried there by the wind from elsewhere. Also, methane typically appears to move along the same latitude, due to the Coriolis effect.

The image indicates a link between seismic activity and destabilization of methane that is held in sediments under the Arctic Ocean. Methane does show up prominently along the fault line that crosses the Arctic Ocean and extends into Siberia over the Laptev Sea.

The Diagram that IPCC failed to include in AR5

The diagram below shows global warming evolving into accelerated warming in the Arctic. Feedbacks such as albedo changes and methane release speed up this process, triggering abrupt climate change and finally extinction.

The Diagram the IPCC failed to include in AR5

This threatening situation calls for an Effective and Comprehensive Climate Plan, such as depicted by the green lines of action in the image below and as further described at the ClimatePlan blog. For more background, see related posts further below.

Related posts

- Just do NOT tell them the monster exists
http://arctic-news.blogspot.com/2013/10/just-do-not-tell-them-the-monster-exists.html

- Methane Release caused by Earthquakes
http://arctic-news.blogspot.com/2013/09/methane-release-caused-by-earthquakes.html

- Climate Plan
http://climateplan.blogspot.com

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Post by Sam Carana.

A RUNAWAY GREENHOUSE EVENT

by John Davies

A linear trendline shows steady growth in the annual increase in CO2 levels, despite promises to reduce emissions.
Furthermore, recent increases show a worrying trend illustrated in the graph by a 4th order polynomial trendline. 

GROWTH RATE OF CARBON DIOXIDE IN THE ATMOSPHERE

The world is probably at the start of a runaway Greenhouse Event which will end most human life on Earth before 2040. This will occur because of a massive and rapid increase in the carbon dioxide concentration in the air which has just accelerated significantly. The increasing Greenhouse Gas concentration, the gases which cause Global Warming, will very soon cause a rapid warming of the global climate and a chaotic climate.

Immediately before the Industrial Revolution, in 1750, the concentration of carbon dioxide in the air which had been stable for millennia, the main Greenhouse gas, was 280 parts per million, but in 2013 it is likely to average 395 parts per million. It has been increasing at an increasing rate since 1750.

In 1960 the carbon dioxide concentration was 315 parts per million and in the 1960’s the concentration was increasing at 0.8 parts per million per year, in the 1980’s at 1.6 parts per million and from 2003 until 2011 inclusive it rose at 2 .0 parts per year.

In 2012 it rose 2.39 parts. Between July 2012 and July 2013 atmospheric carbon dioxide increased in concentration by 3.35 parts, by far the largest 12 month increase ever.

THIS HUGE INCREASE SHOULD BE PUBLISHED EVERYWHERE WORLDWIDE NOW

ASSESSMENT

When there have been large anomalous increases in the past, though nothing like this, there has been a rapid return to near normal but this is probably slightly different. The most likely growth in the calendar year 2013 is likely to be about 2.85 parts per million, a calendar year record , but much below the growth from July 2012 until July 2013. The growth for 2012 and 2013 is likely to average out at about 2.62 parts per million, a record for a two year period.

Again, looking to the past, when there has been a rise in concentration like we will have had in 2012 and 2013 the rate of increase in concentration diminishes for a couple of years before rising again. I would expect the rise in concentration in 2014 and 2015 to average 2.55 parts per million before rising at an increasing rate thereafter assuming the world carries on with business as usual. Nevertheless this average rate is faster than we have yet witnessed except for the 2012 and 2013 period. This rate of increase is much faster than that which preceded the greatest ever wipe out of life on earth 249 million years ago.

There is a significant uncertainty about the above growth rate in the near term, with a chance of a higher and lower growth rate though the above forecast is the most likely outcome.

There must be a small chance that this is really the start of a very fast runaway event. Should the growth rate of atmospheric carbon dioxide in 2013 be greater than about 3.1 parts per million then the world will probably have entered a very fast runaway event.

It is even more absolutely critical that carbon dioxide concentrations from August 2013 onwards are rising at a slower rate than between July 2012 and July 2013 otherwise the world will have entered a very fast runaway Greenhouse Event. Carbon Dioxide concentrations will almost certainly be rising at a slower rate from August 2013 onwards.

The runaway greenhouse event, or a very fast runaway Greenhouse Event is probably just starting, and can only be stopped by an immediate response. The danger is that it will very rapidly run out of our control. I think the net negative feedback to greenhouse gas emissions is just starting to diminish. It is not clear whether this is because the sinks are absorbing less carbon dioxide or a form of positive feedback is starting probably a bit of both.

The rising carbon dioxide levels will probably lead to rising global temperatures from about 2015 onwards which will cause more climatic disruption, especially severe droughts, and thus more carbon emissions almost certainly before 2020.

This is going to occur at a time when the Arctic Ocean will probably become free of sea ice leading to a different set of runaway events which will coalesce with the build-up of carbon dioxide in the atmosphere.

This will lead to societal collapse after rising global temperatures have caused severe droughts and a global famine at some time prior to 2040, but probably much sooner in about 2020 or in the 2020’s.

IMMEDIATE ACTION IS CRUCIAL

The absolute priority is that the world’s public and politicians are told about the rapidly increasing rate of carbon dioxide concentrations in the air which will cause a runaway Greenhouse Event, both in the media and in social media. The gravity of the situation needs to be accepted and all nations agree to co-operate to solve the problem.

There needs to be a world conference at which all nations agree the grave situation that the world is facing and that urgent and drastic action is essential. They need to accept and agree that all nations will cut greenhouse gas emissions to an accepted and equal low level of emissions per person. This will mean that only nations with very small emissions per person like the Central African Republic will not need to make any emission cuts. The rate of increase in Carbon Dioxide needs to be cut to 2 parts per million per annum by 2015 onwards. The arctic needs to be cooled so that the sea ice does not all melt before the end of the Arctic Summer.

Reducing the rate of carbon dioxide build-up in the atmosphere will be astoundingly difficult. Emissions must be cut drastically, but this will lead to a reduction of Sulphate aerosols in the atmosphere, which might cause temperatures to rise and more carbon to be emitted from biomass as droughts become more severe. The solution is to try the relatively easy route and then use geo-engineering as necessary. This involves huge societal changes, a more egalitarian society and a smaller global economy, but if it is not done almost everybody will die.

Secondly, a group of scientists needs to be formed under the authority of the United Nations to formulate geo-engineering technologies, to go together with cuts in emissions, to reduce the carbon dioxide content of the atmosphere, such as planting forests, and to cool the arctic to save the arctic sea ice.

The immediate priority is to accept the gravity of the situation and that all nations and peoples will co-operate to solve the problem.

These measures will give humanity a chance of saving civilization.

Post by Sam Carana.

Climate change fighting town savaged by runaway oil train

by Paul Beckwith

Early in the morning on Saturday July 6th, 2013 five locomotives and 73 tank cars carrying crude oil were parked about 12.5 km uphill (track distance) from the small idyllic Quebec town of Lac-Mégantic about 210 km east of Montreal. Apparently, the sole train engineer had finished his shift and left the train (locomotives running) a few hours earlier to get some sleep in the town; the train sat unmanned awaiting the arrival of the next engineer. Something went horribly wrong; the tank cars uncoupled from the locomotives and started rolling downhill and gathering speed as they headed towards the small town.

Map 1 (from http://www.bbc.co.uk/news/world-us-canada-23221939 ) shows the town location within the province of Quebec in Canada and the general route of the oil train near the town. North is upward for all of the following maps.

Map 1

Map 2 below shows a satellite image from Google Earth of the town and nearby lake.  The red vertical line is for scale, with a length representing a 15 km distance.

Map 2

Map 3 shows a closer-up view of the town. The dark pathway is the route of the train tracks crossing the town from west-north-west to the south-east. This Google Earth image is several years old, and rail cars can be seen at the time this image was obtained beyond the track curve towards the south-east. The train track forks into a northward and southward curving line where it crosses a major road.

Map 3

Map 4 shows an even closer view of the region. The yellow line of length 0.2 km indicates the scale. Buildings within the red zone that I outlined by freehand were leveled as the train jumped the track near the fork and plowed along the orange path. I marked red dots on the individual structures within the red zone of destruction, and counted about 40 buildings. Most of these buildings were completely leveled, with the exception of a few near the perimeter of the red zone that were severely damaged.

Map 4

Map 5 indicates the general location where the train was parked and uncoupled from the 5 locomotives, in the town of Nantes, for the shift change. This Google Earth image from 2012 has an elevation of 519 m above mean sea level on the tracks at the location where some train cars are seen in this older image. This location has the highest elevation and drops off to either side along the tracks as determined from Google Earth elevations.

Map 5

Thus, from Google Earth the elevation of Nantes is determined to be roughly 519 meters, while that of the derailment zone in Lac-Mégantic is 399 meters. From simple physics, the potential energy of the train at Nantes (PE = mgh; m=mass, g=9.81 m/s², h= height) was converted to kinetic energy at the derailment site (KE=0.5mv2). Solving for the speed of the train the mass cancels out giving v = sqrt(2*g*h) giving a value of 48.5 m/s (175 km/hr = 109 mph) which was clearly enough to cause the derailment if correct. This speed is an upper limit value, assuming no rolling resistance or air resistance or tank car braking. The actual number is certainly somewhat lower, but the amount is difficult to calculate exactly but we will estimate it. Assuming constant acceleration of the train down the hill, the time to reach the town after starting from rest at the top of the hill is given by t = 2x/v (x=length of track between locations = 12.5 km, v = speed at bottom of hill) gives a rolling time of 515 seconds (8 minutes, 35 seconds). The average acceleration along the track path down the hill is a=v/t=0.09417 m/s² (or about 0.96% of the acceleration due to gravity). Again, this is for the no friction case, modifications for friction will be estimated shortly.

Map 6 shows the route connecting Nantes to Lac-Mégantic. The rail distance is roughly 12.5 km as measured on Google Earth and indicated by the yellow lines (connecting the red point tie dots along the track), and the vertical height change is 120 meters along this path down to the derailment site. The runaway train successfully negotiated two very sharp curves. The first is at Laval-Nord (elevation 457 m, height drop from Nantes of 62 m) giving a calculated speed of 34.9 m/s (126 km/hr), a derailment here would have taken the train into forests. The second sharp curve is 0.38 km north of the lake (elevation 431 m, height drop 88 m) with a calculated speed of 41.6 m/s (150 km/hr). Failure to negotiate the second curve would have been a derailment into the forests, and would have likely spilled crude oil that would drain into the lake.

Map 6

Map 7 from this link (map http://www.cbc.ca/news/interactives/before-after/lac-megantic/ba.html, north is down on this map) is a sliding before-and-after image that shows the buildings that were destroyed in the derailment and explosions. The after-image is also shown below. One can count 44 pancaked tank cars piled up alongside one another. The train came from the west (right side on this image which has north pointing downward) and the lead cars traveled a distance of at least 200 meters after leaving the rails. It is unclear where the other 30 or so tank cars are, presumably they still along the track behind the derailed cars (to the right on the image below).

Map 7

Some background history/information on the town can be found in this linked article: (http://www.ctvnews.ca/canada/lac-megantic-history-of-a-picturesque-quebec-forestry-town-1.1357424 ).
Quoting from this article:
“According to the (town) website, it was one of 52 municipalities in Quebec to receive a "Four Blossoms" rating from the provincial organization "Les Fleurons du Quebec," which rewards municipalities for attractive greenery. It was also ranked among the first eight municipalities in Quebec to earn a "Carbon responsible" attestation, for climate-change measures, from the Enviro-access consulting company.”

Awards won by Lac-Mégantic
for climate-change measures

This award winning, climate change fighting town had no chance against the runaway oil train; which is an incredibly sad irony. Unfortunately, the train successfully negotiated two very sharp curves at speeds of 34.9 m/s and 41.6 m/s prior to entering the town of Lac-Mégantic. Derailment on either of these curves would have spared the town. In the town it derailed at roughly 48.5 m/s on a much more gradual turn crossing near or at a major road. As mentioned earlier, these speeds are upper limit speeds assuming no rolling resistance or air resistance and an on-track acceleration calculated from the basic physics of constant acceleration to be 0.96% of gravity. What is the effect of friction? If we assume a 20% reduction due to friction (rolling + aerodynamic + tank car braking) then acceleration is reduced to 0.07534 m/s², rolling time is increased to 576 seconds, and derailment speed is reduced to 43.4 m/s (156 km/hr or 97 mph).

Still this is an incredibly fast speed that is hard to believe. Is this ridiculous? Re-examine the images (Map 7) above of the wreck zone, and observe that for more than half the train to completely derail and pancake (>44 tank cars) required an extremely high derailment speed. Going even one step further, let us now assume that there was even more friction, for example from more hydraulic braking action on the individual tank cars, such that the total frictional acceleration reduction was reduced by 50% to 0.0478 m/s². Rolling time and derailment speed would respectively now become 723 seconds and 34.6 m/s (125 km/hr or 78 mph). I doubt this is fast enough to cause the level of pancaking and derailment distance observed, so my guess on the derailment speed would be between the two previous numbers. The train “black-box” should come out with accurate numbers after it is analyzed.

Given that train tank car transport of crude oil has increased by 28,000% in the last 5 years (http://www.huffingtonpost.ca/2013/07/07/lac-megantic-explosion-oil_n_3558647.html ) without a corresponding increase in safety inspections (and even cost cutting reductions) it is virtually certain that the frequency of accidents will increase. Pipelines are no answer to transporting oil, given that we are undergoing abrupt climate change. In fact, increases in the frequency, severity, and geographical regions of extreme weather events due to jet stream behavior completely changing due to rapid climate change is also greatly increasing the risk of oil transport by rail and pipeline from flooding, drought, heat waves, and extremely large temperature swings over short periods of time. In fact all infrastructure is being severely compromised by extreme weather. As the people in Calgary, Toronto, India, Europe, and many other places around the world are discovering first hand.

Paul Beckwith is a part-time professor with the laboratory for paleoclimatology and climatology, department of geography, University of Ottawa. He teaches second year climatology/meteorology. His PhD research topic is “Abrupt climate change in the past and present.” He holds an M.Sc. in laser physics and a B.Eng. in engineering physics and reached the rank of chess master in a previous life.

Earth is on the edge of runaway warming

Earth within our solar system's habitable zone

How well is Earth's orbit around the sun positioned within the boundaries of the habitable zone? The illustration by the Wikipedia image on the right would give that impression that Earth was comfortably positioned in the middle of this zone.

What is the habitable zone? To be habitable, a planet the size of Earth should be within certain distances from its Sun, in order for liquid water to exist on its surface, for which temperatures must be between freezing point (0° C) and boiling point (100° C) of water.

In the Wikipedia image, the dark green zone indicates that a planet the size of Earth could possess liquid water, which is essential since carbon compounds dissolved in water form the basis of all earthly life, so watery planets are good candidates to support similar carbon-based biochemistries.

If a planet is too far away from the star that heats it, water will freeze. The habitable zone can be extended (light green color) for larger terrestrial planets that could hold on to thicker atmospheres which could theoretically provide sufficient warming and pressure to maintain water at a greater distance from the parent star.

A planet closer to its star than the inner edge of the habitable zone will be too hot. Any water present will boil away or be lost into space entirely. Rising temperatures caused by greenhouse gases could lead to a moist greenhouse with similar results.

The distance between Earth and the Sun is one astronomical unit (1 AU). Mars is often said to have an average distance from the Sun of 1.52 AU. A recent study led by Ravi Kopparapu at Penn State mentions that early Mars was warm enough for liquid water to flow on its surface. However, the present-day solar flux at Mars distance is 0.43 times that of Earth. Therefore, the solar flux received by Mars at 3.8 Gyr was 0.75 × 0.43 = 0.32 times that of Earth. The corresponding outer habitable zone limit today, then, would be about 1.77 AU, i.e. just a bit too far away from the Sun to sustain water in liquid form. Venus, on the other hand, is too close to the Sun (see box below).

Kopparapu calculates that the Solar System’s habitable zone lies between 0.99 AU (92 million mi, 148 million km) and 1.70 AU (158 million mi, 254 million km) from the Sun. In other words, Earth is on the edge of runaway warming.

Image by Kopparapu et al. New calculations show that Earth is positioned on the edge of the habitable zone (green-shaded region), boundaries of which are determined by the moist-greenhouse (inner edge, higher flux values) and maximum greenhouse (outer edge, lower flux values)

Kopparapu says that if current IPCC temperature projections of a 4 degrees K (or Celsius) increase by the end of this century are correct, our descendants could start seeing the signatures of a moist greenhouse by 2100.

Kopparapu argues that once the atmosphere makes the transition to a moist greenhouse, the only option would be global geoengineering to reverse the process. In such a moist-greenhouse scenario, not only are the ozone layers and ice caps destroyed, but the oceans would begin evaporating into the atmosphere's upper stratosphere.

Venus' runaway greenhouse effect a warning for Earth by Sam Carana - first posted November 28, 2007, at: http://global-warming.gather.com/viewArticle.action?articleId=281474977189423 Venus was transformed from a haven for water to a fiery hell by an runaway greenhouse effect, concludes the European Space Agency (ESA), after studying data from the Venus Express, which has been orbiting Venus since April 2006. Venus today is a hellish place with surface temperatures of over 400°C (752°Fahrenheit), winds blowing at speeds of over 100 m/s (224 mph) and pressure a hundred times that on Earth, a pressure equivalent, on Earth, to being one km (0.62 miles) under the sea. Hakan Svedhem, ESA scientist and lead author of one of eight studies published on Wednesday in the British journal Nature, says that Earth and Venus have nearly the same mass, size and density, and have about the same amount of carbon dioxide. In the past, Venus was much more Earth-like and was partially covered with water, like oceans, the ESA scientists believe. How could a world so similar to Earth have turned into such a noxious and inhospitable place? The answer is planetary warming. At some point, atmospheric carbon triggered a runaway warming on Venus that boiled away the oceans. As water vapour is a greenhouse gas, this further trapped solar heat, causing the planet to heat up even more. So, more surface water evaporated, and eventually dissipated into space. It was a “positive feedback” -- a vicious circle of self-reinforcing warming which slowly dessicated the planet. “Eventually the oceans began to boil”, said David Grinspoon, a Venus Express interdisciplinary scientist from the Denver Museum of Nature and Science, Colorado, USA. “You wound up with what we call a runaway greenhouse effect”, Hakan Svedhem says. Venus Express found hydrogen and oxygen ions escaping in a two to one ratio, meaning that water vapor in the atmosphere the little that is left of what they believe were once oceans is still disappearing. While most of Earth's carbon store remained locked up in the soil, rocks and oceans, on Venus it went into the atmosphere, resulting in Venus' atmosphere now consisting of about 95% carbon dioxide. “Earth is moving along the curve that connects it to Venus”, warns Dmitry Titov, science coordinator of the Venus Express mission. References - Venus Express - European Space Agency (ESA) http://www.esa.int/SPECIALS/Venus_Express/SEMGK373R8F_0.html - Venus inferno due to 'runaway greenhouse effect', say scientists http://www.physorg.com/news115477239.html - Probe likens young Venus to Earth http://physicsworld.com/cws/article/news/32018 - European mission reports from Venus http://www.nature.com/nature/journal/v437/n7062/full/4371071a.html

References

- Habitable zones around main-sequence stars: new estimates

Ravi Kumar Kopparapu et al. 2013

http://iopscience.iop.org/0004-637X/765/2/131

- Habitable Zone - Wikipedia

http://en.wikipedia.org/wiki/Habitable_zone

- Earth is closer to the edge of Sun's habitable zone

http://physicsworld.com/cws/article/news/2013/mar/25/earth-is-closer-to-the-edge-of-suns-habitable-zone

- Updated model for identifying habitable zones around stars puts Earth on the edge

http://www.gizmag.com/habitable-zone/26051/

THE TRAGIC FAILURE OF THE SCIENTIFIC COMMUNITY TO ISSUE ADEQUATE WARNING RE: THE ARCTIC TIPPING POINT EMERGENCY

by Gary Houser

"Our greatest concern is that loss of Arctic sea ice creates a grave threat of passing two other tipping points -- the potential instability of the Greenland ice sheet and methane hydrates. These latter two tipping points would have consequences that are practically irreversible on time scales of relevance to humanity." [1]  ....."We are in a planetary emergency." [2] - World renowned climate scientist Dr. James Hansen

The scientific community must be commended for its efforts to convey to the world the reality of climate disruption caused by carbon dioxide (CO2) emissions. That world is now grappling with the politics of whether effective reductions can be achieved in time. But there appears to be a new danger emerging from the Arctic which threatens to accelerate such disruption beyond the reach of any meaningful control. Cutting edge researchers in the field are observing large plumes of methane rising from the shallow seabeds. [3] Others are discovering heightened levels through airborne measurement. [4]  According to the most recent Intergovernmental Panel on Climate Change (IPCC) report, methane is a global warming gas no less than 72 times more powerful than CO2. [5]

In the course of working on a documentary [6] on this super greenhouse gas and the frightening prospect that such is beginning to thaw and release to the atmosphere in the Arctic, the author has encountered a highly disturbing "disconnect". On the one hand, there are highly eminent scientists - such as James Hansen - warning that the situation in the Arctic could well lead to the crossing of an "irreversible tipping point". On the other hand, such warning is not finding its way into the major scientific reports which government policy makers will use to chart their response. It cannot be found in either the draft of the new IPCC report or the draft of the U.S. National Climate Assessment.

As global climate disruption begins to enter the realm of "tipping points of no return", humanity is coming face to face with a moral crisis inextricably linked to the physical crisis. Scientists are first and foremost human beings. If information is discovered that points to a real possibility that a given situation can abruptly escalate into an existential threat to human survival, there is a profound moral responsibility to issue a loud and unambiguous warning.

There are now several indicators that the factors which could generate such a threat are indeed lining up in the Arctic - such as the ice collapse and the loss of solar reflectivity that will only accelerate further Arctic warming. At this time however, other than a handful of notable exceptions, the scientific community as a whole is utterly failing to issue such warning. This essay is an attempt to grapple with what might be the systemic reasons for such failure. Although the author is not a scientist and addresses the issue from outside that frame of reference, reasons are provided for why such may be an advantage rather than a disadvantage.

The climate science community around the world is performing a tremendous service to humanity. As climate disruption continues to escalate and the threat to our society becomes more grave, its members have worked long hours - in many cases on their own time - to gather the relevant data. As only one example. documentary-related exchanges between the author and scientists working in the Arctic make clear that much personal hardship and sacrifice are being endured in order to conduct such research.

It is well known that in preparation for their work, scientists are taught to exercise great caution in reporting their findings and never stray beyond that for which there is incontrovertible evidence. Even when it appears evidence is present, it is the time-honored tradition of science to still submit any conclusions drawn from such to their peers for review.

In almost every case, this strict methodology has well served the public interest. It has filtered out errors and made solid information available to the public and policy makers. But in the arena of global climate disruption, humanity is now facing something unique and quite un-paralleled by any other issue. There is a point in the process of climate de-stabilization where colossal natural forces can be unleashed which are capable of developing their own unstoppable momentum and spiralling well beyond the reach of human control. When such occurs - the already mentioned "irreversible tipping point".

Though a term used frequently in discussions on climate, its full meaning and magnitude have rarely been taken to heart. Far too often, it is simply another "buzzword" dropped into an article and treated only in the most superficial way. Indeed, such usage seems almost to "anesthetize" us to the horrific reality it points toward. In truth, the crossing of some kinds of tipping points can lead to the crushing of our entire civilization on no less of a scale than nuclear war. The devastation can be so sweeping that the concept of "adaptation" becomes meaningless. "Irreversible" refers to the brutal fact that once humanity allows this process to become triggered, there will be no chance to go back, no chance to learn from our mistakes and correct them.

Of the several tipping point scenarios which are possible, one considered especially frightening is the prospect of triggering an abrupt and large scale methane release in the shallow seabeds along Arctic coastlines. The entire climate debate has been dominated by a discussion of humanity's contribution to the problem - which has been the emission of carbon dioxide since the beginning of the industrial age. What science has discovered is that nature has its own vast storehouse of ancient carbon trapped in the ice of the polar regions.

The scenario of most concern to methane "specialists" is what's known as the "runaway feedback" reaction. As described by Dr. Ira Leifer of the Marine Science Institute at the Univ. of Calif.: "A runaway feedback effect would be where methane comes out of the ocean into the atmosphere leading to warming, leading to warmer oceans and more methane coming out, causing an accelerated rate of warming in what one could describe as a runaway train." [7]  A cycle would be initiated which feeds upon itself and therefore becomes unstoppable.

When one looks at the history of the most devastating "wipeouts" of life on earth - such mass extinction events as the PETM or the end-Permian - it is sobering to learn that large scale release of methane has been pointed to as a "probable cause". World-renowned climate science pioneer Dr. James Hansen relates methane to the PETM extinction event:

"There have been times in the earth's history when methane hydrates on the continental shelves melted and went into the atmosphere and caused global warming of six to nine degrees Celsius, which is 10 to 18 degrees Fahrenheit." [8]

The end-Permian extinction was the most colossal mass extinction event, wiping out over 90% of the life forms on earth. According to paleontologist Michael Benton - considered by some to have written the definitive book on this event (When Life Nearly Died):

"Normally, long-term global processes act to bring greenhouse gas levels down. This kind of negative feedback keeps the Earth in equilibrium. But what happens if the release of methane is so huge and fast that normal feedback processes are overwhelmed? Then you have a "runaway greenhouse"...... As temperatures rise, species start to go extinct. Plants and plankton die off and oxygen levels plummet. This is what seems to have happened 251 million years ago." [9]

While devastation on this level is inherently difficult to grasp, one attempt to convey such is provided in the documentary "Miracle Planet". [10] Though absolute certainty on causation may not be attainable, just the possibility that our society may be triggering a force with this kind of power is mind-boggling enough.

Could anything of this unspeakable magnitude be triggered by thawing methane in the Arctic? Again Ira Leifer: "The amount of methane that’s trapped under the permafrost and in hydrates in the Arctic areas is so large that if it was rapidly released it could radically change the atmosphere in a way that would be probably unstoppable and inimicable to human life." [11]  Hansen adds: "It is difficult to imagine how the methane clathrates could survive, once the ocean has had time to warm. In that event a PETM-like warming could be added on top of the fossil fuel warming." [12]  Dr. Hansen - along with Arctic ice and methane experts - address this issue in more depth in a documentary co-produced by the author. [13]

Methane plumes rising from the seafloor

In examining the key reports being made by the scientific community - such as drafts for the new IPCC document and the National Climate Assessment (of the U.S.), one might expect there to be dire warnings about a potential "point of no return" if these forces are unleashed. We do find a discussion of the various consequences of climate disruption that are hitting right now - Arctic and glacial melt, extreme weather, more powerful hurricanes and storms, increases in drought, food shortages, wildfires, and flooding. But where is the discussion of what these symptoms of disruption are leading to? One of the most frightening spectres looming over humanity - the tipping point of a methane "runaway" - is completely ignored.

How can this be possible? Several factors may be combining. As stated earlier, scientists are trained to only make statements based on "hard evidence". In the case of a potentially abrupt methane runaway, it is not possible to pinpoint a specific moment in time when such may be initiated. It cannot be stated with certainty whether this will happen in 2017, 2027, or 2037. Without this ability to pinpoint and quantify, the response of science has been to simply not address it.

Secondly, scientists are human. All of us have great difficulty in truly facing and absorbing the full implications of a complete collapse of human society and even a wiping out of most or all life on the planet. It is human to utilize methods of psychological denial to block out such a staggeringly horrific threat to our collective existence. In this instance, scientists are no different. Unless there is "absolute proof" staring us in the face, the overwhelming tendency is to push such thoughts out of our consciousness so we can "get on with our day".

A third factor is that the current methodology for the reporting of climate science is fundamentally flawed and dysfunctional in regard to the challenge at hand. The single most important such report is that issued by the Intergovernmental Panel on Climate Change (IPCC). It is based on a consensus process and an intensively time-consuming level of peer review. Under normal circumstances, such would be seen as positives. But in a situation where humanity may come under severe threat in the very near term future, these reports are essentially looking backward at where science has been for the past 7 years rather than reporting the cutting edge trend lines. A glaring example is how the IPCC completely missed on predicting the speed at which the Arctic would melt.

The tremendous danger with this situation is that by the time any kind of "absolute proof" is gathered, it will very likely be too late to stop the conditions bringing on the dreaded runaway reaction. An unspeakably terrifying process will already have been set into motion and humanity at that point will be helpless to stop it. Temperatures on earth could eventually skyrocket to a level where mass famine is initiated.

What are the potential solutions to these terrible problems? One would be procedural. A special section of such reports should be dedicated to communicating the work of those scientists whose research is on the cutting edge of dealing with potentially huge climate impacts and yet still "in progress" in terms of gathering the relevant data. For example, even though the precise timing of a methane runaway cannot be predicted, there should be a report on the trend lines and the extent to which the conditions that could bring on a runaway are manifesting. If those conditions are lining up to a considerable extent, then an appropriate warning should be issued.

A second corrective step is more related to basic philosophy and morality. At the Earth Summit in Rio in 1992, representatives of the world's nations agreed to apply the precautionary principle in determining whether an action should go forward to prevent irreversible damage to the environment. Principle #15 of the Rio Declaration [14] states that:

"In order to protect the environment, the precautionary approach shall be widely applied by States according to their capabilities. Where there are threats of serious or irreversible damage, lack of full scientific certainty shall not be used as a reason for postponing cost-effective measures to prevent environmental degradation."

In a further treatment of the meaning of the precautionary principle, it has been stated that there must be

"a willingness to take action in advance of scientific proof of evidence of the need for the proposed action on the grounds that further delay will prove ultimately most costly to society and nature, and, in the longer term, selfish and unfair to future generations." [15]

A methane runaway in the Arctic more than meets the criteria of being a "threat" which can bring about "irreversible damage". Due to its potential to create an unstoppable wave of continually rising temperatures capable of initiating something as horrendous as a mass extinction event, its irreversible damage could be of the most frightening magnitude imaginable. If humanity failed to recognize this danger and allowed its occurrence, such would most certainly constitute an irreparable crime against future generations. The most fundamental tenet of human morality demands that in such a unique situation the scientific community act on the basis of the precautionary principle and issue the appropriate warning.

In his powerful book on the ethics of nuclear war, Jonathan Schell wrote: "To kill a human being is murder, but what crime is it to cancel the numberless multitude of unconceived people?" [16] In the words of the ecological ethicist David Orr: "Climate destabilization, like nuclear war, has the potential to destroy all human life on Earth and in effect 'murder the future'......... Willfully caused extinction is a crime that as yet has no name." [17]

Is it possible that the very pillar of science which has served our society so well - the uncompromising demand for incontrovertible "evidence" - has in this unprecedented current crisis become a dangerous obstruction? Is it possible that this requirement of absolute "proof" is creating a perceptual blindness that could pave the way for the most horrendous suffering in the history of civilization?

To the scientists who may read this essay, an appeal is made in the name of our collective humanity to truly confront and grapple with the meaning of the term "irreversible" and weigh the potentially horrific consequences of silence. It is no violation of scientific "objectivity" to look at trend lines and determine whether their continued trajectory might well carry our civilization over the cliff. And if this possibility is there, is there not a profound moral obligation under the precautionary principle to issue a loud and unambiguous warning to humanity?

Before arriving at an answer, the reader - and especially any member of the scientific community - is invited to view a powerful film that is simply entitled "HOME". [18] In this artistic masterpiece, images of life on earth convey beyond the reach of words the incredible magnificence of what will be lost if climate disruption is allowed to escalate into an unstoppable "wipe-out". It also describes the methane lurking in the Arctic as a "climatic time bomb". Please watch and please speak out before it is too late. As James Hansen says: "We are in a planetary emergency."

LINKS

[1] Bloomberg, August 17, 2012
[2] AFP: 'Planetary emergency' due to Arctic melt, experts warn
[3] Vast methane 'plumes' seen in Arctic ocean as ... - The Independent
[4] Danger from the deep: New climate threat as methane rises from ...
[5] www.ipcc.ch/publications_and_data/ar4/wg1/en/tssts-2-5.html
[6] [Documentary co-produced by author]: Arctic News: Arctic methane: Why the sea ice matters
[7] Interview with Leifer for documentary
[8] Interview with Hansen http://youtu.be/ACHLayfA6_4
[9] Wipeout: the end-Permian mass extinction
[10] 6 minute clip from "Miracle Planet": http://youtu.be/exfNNDExxIc
[11] Interview with Leifer for documentary
[12] Hansen's book: Storms of My Grandchildren: The Truth About the Coming Climate ...
[13] Same as link at #6
[14] Rio Declaration
[15] www.dieoff.org/page31.htm
[16] The Fate of the Earth - The New York Times
[17] Thinking About the Unthinkable by David Orr We ... - Moral Ground
[18] [Link to free full film]: http://www.youtube.com/watch?v=jqxENMKaeCU