Gas Well Blowout at Porter Ranch, California Sickening Residents

Monster Gas Leak Spewing up to 50,000 kg/hr of  powerful GHG

The massive gas leak at a natural gas storage well at Aliso Canyon storage field in Northridge, California, operated by SoCalGas, has released about 75,000 metric tons of methane since it was discovered on October 23, 2015.

The leak is currently spewing about 33,000 – 50,000 kg/hr of the GHG, which is said to be the equivalent of a quarter of the state’s total methane emissions from all sources.

The emissions are making the residents sick. Thousands of the residents have experienced nausea, dizziness, vomiting, nosebleeds, and headaches among other symptoms from the hazardous gas.

Some 6,500 families have filed for help, but only about 2,250 have since been relocated, with another 100 or so staying with family or friends.

New video shot with a highly specialized Optical Gas Imaging camera shows time-lapse image of Southern California Gas Co.’s Aliso Canyon gas leak. Video depicts an ominous cloud of methane gas flowing down from the gas well over the community of Porter Ranch. The video shows the gas cloud at 60x speed. For more information visit: http://porterranchlawsuit.com/

Relocating Schools

The Board of Education took action last week to expedite the temporary relocation of Castlebay Lane Charter and Porter Ranch Community School, comprising a total of about 1,900 students, due to disruptions in teaching and learning caused by the methane leak in Aliso Canyon.

“When classes resume after the winter break, the 770 students in grades K-5 who attend Castlebay Lane will be relocated to Sunny Brae Avenue Elementary in Winnetka. Porter Ranch Community School, which has 1,100 students in grades K-8, will relocate to Northridge Middle School. Portable classrooms and available space at the host schools will be used to house the Castlebay Lane and Porter Ranch students, teachers and staff.”

SoCalGas in Aliso Canyon, outside of Los Angeles, has released the following in its latest report on the blowout.

Relief Well  [BPesque?]

Efforts to drill the relief well are progressing. Crews are actively working on Phase 3 of a 5 phase process. This potentially time consuming phase is critical to the overall success, and encompasses positively identifying the leaking well with active magnetic ranging technology. Once identified, the relief well will follow the leaking well to more than 8,000 feet deep and intercept it near its bottom. Once we intercept the well, we will pump heavy mud and fluids into the leaking well to stop the flow of gas from the reservoir and into the well. Once the flow of gas has been stopped, we will pump cement into the bottom of the well to permanently seal it. The drilling process continues around the clock, and is expected to be completed by late February to late March.

As of December 27, we have successfully located the leaking or target well using the active magnetic ranging tool and are preparing to resume drilling.  We have currently drilled approximately 3,800 feet of measured depth.  From this point on, we will be interchanging drilling and ranging equipment as needed to increase the precision of the relief well in relation to the target well’s location and to follow it down at the appropriate distance, angle and orientation.

We are also initiating a secondary relief well as backup to our ongoing drilling of the primary relief well. Grading of the drilling pad for the secondary well should be complete in early January.  At that point a drilling rig will be moved in and set up.  Drilling is slated to begin in late January.

Tap Water Catches Fire in North Dakota

FRACKED IN NORTH DAKOTA
.

N.D. resident sets tap water on fire

Jacob Haughney, who works in North Dakota oil fields, has made a video in which he sets his tap water on fire with a lighter.

There’s “nothing like a refreshing glass of fire…  First time I did it, it was a huge fireball [and] took up the entire sink—so that’s why I’m a little jumpy doing it. I don’t want to blow up the bathroom here,” he explains, laughing during the demonstration.

How to set tap water on fire in two steps, as shown by the N.D. resident Jacob Haughney.

High concentration of methane in the water may be responsible  for the flammable water, according to the experts.

North Dakota has experienced a fracking boom over the past few years. It’s currently the second largest oil-producing state in the US, with about 912,000 barrels of shale gas per day.

Gasland 2010

In the 2010 award winning documentary “Gasland 2010,”  filmmaker Josh Fox travel across 32 states meeting other rural residents on the front lines of fracking. “He discovers toxic streams, ruined aquifers, dying livestock, brutal illnesses, and kitchen sinks that burst into flame.”

GASLAND Trailer 2010

Global Disasters/ Significant Events – Nov 26, 2013

​US releasing 50% more methane than EPA reported: Study

The United States has been releasing 50 percent more methane, a greenhouse gas, than previous EPA estimates, according to a new study released by the Proceedings of the National Academy of Science.

The new study estimates the US released 49 million tons of methane into the air in 2008, or  more than the 32 million tons, which is 1.5 times higher than that estimated by the US Environmental Protection Agency (EPA).

The figure is also 1.7 times higher than the estimate released by international Emissions Database for Global Atmospheric Research (EDGAR), a rubber-stamp outfit set up by the European Commission.

Methane is produced in a several ways including leaks during oil and gas exploration and refining, growing rice and livestock manure. Most of the U.S. methane is released in Texas, Oklahoma and Kansas.

Methane is a potent greenhouse gas with about 21 times greater heat-trapping ability per molecule than carbon dioxide.

The atmospheric concentration of methane has more than doubled since preindustrial times, climbing from about 700ppb to 1,826 ppb in 2012.

Methane has a boiling point of −161°C (−257.8°F) at one atmosphere, and is flammable only in concentration range of 5–15% in air.

Greedy Amazon Working Employees to the Bone

An undercover employee had to walk 11 and collect orders every 33 seconds.

An expert said such working conditions could cause “mental and physical illness,” reported BBC.

“Amazon reported UK sales of £4.8 billion [$7.8] last year. It employs around 20,000 staff in the UK during the Christmas period. On the company’s busiest day in December last year, 3.5million items were ordered by customers.”

The undercover reporter was employed as a “picker” collecting orders from 800,000 sq ft of storage. Because he worked night shifts his pay before tax rose from the daily rate of £6.50 [$10.53] per hour to £8.25 per hour.

 

This post will be updated throughout the day …

GHG Concentrations Climbed to New Highs in 2012: WMO

Atmospheric greenhouse gases reached new record levels

Atmospheric concentrations of major greenhouse gases responsible for climate change climbed to new records in 2012, according to WMO Greenhouse Gas Bulletin (No. 9: November 2013) released by the World Meteorological Organisation (WMO).

Levels of CO₂, the primary greenhouse gas produced by human activities, grew by 2.2 ppm, higher the average of 2.02 ppm over the past decade. At 393.1 parts per million (ppm), the 2012 CO₂ concentrations were 41 percent above the pre-industrial level.

The latest analysis of observations from the WMO Global Atmosphere Watch (GAW) Programme shows that the globally averaged mole fractions of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) reached new highs in 2012, with CO₂ at 393.1±0.1 ppm, CH₄ at 1819±1 ppb and N₂O at 325.1±0.1 ppb. These values constitute, respectively, 141%, 260% and 120% of pre-industrial (before 1750) levels. The atmospheric increase of CO₂ from 2011 to 2012 is higher than the average growth rate over the past 10 years. For N₂O the increase from 2011 to 2012 is smaller than the one observed from 2010 to 2011 but larger than the average growth rate over the past 10 years. Atmospheric CH₄ continued to increase at a rate similar to the one observed over the past 4 years. The National Oceanic and Atmospheric Administration (NOAA) Annual Greenhouse Gas Index shows that from 1990 to 2012 radiative forcing by long-lived greenhouse gases increased by 32%, with CO₂ accounting for about 80% of this increase.

This ninth WMO/GAW Annual GHG Bulletin reports atmospheric abundances and rates of change of the most
important long-lived greenhouse gases (LLGHGs) – carbon dioxide, methane, nitrous oxide – and provides a summary of the contributions of the other gases. These three together with CFC-12 and CFC-11 account for approximately 96% of radiative forcing due to LLGHGs.

The NOAA Annual Greenhouse Gas Index (AGGI) in 2012 was 1.32, representing a 32% increase in total radiative forcing (relative to 1750) by all LLGHGs since 1990 and a 1.2% increase from 2011 to 2012 (Figure 1). The total radiative forcing by all LLGHGs in 2012 corresponds to a CO₂-equivalent mole fraction of 475.6 ppm (http://www.esrl.noaa.gov/gmd/aggi).

 Carbon dioxide (CO2) is the single most important anthropogenic GHG in the atmosphere

Carbon dioxide is the single most important anthropogenic greenhouse gas in the atmosphere, contributing ~64%  to radiative forcing by LLGHGs. It is responsible for ~84% of the increase in radiative forcing over the past decade and ~82% over the past five years. The pre-industrial level of ~278 ppm represented a balance of fluxes between the atmosphere, the oceans and the biosphere. Atmospheric CO₂ reached 141% of the pre-industrial level in 2012, primarily because of emissions from combustion of fossil fuels (fossil fuel CO₂ emissions 9.5±0.5 PgC in 2011, according to http://www.globalcarbonproject.org), deforestation and other land-use change (0.9±0.5 PgC in 2011). The average increase in atmospheric CO₂ from pre-industrial time corresponds to ~55% of the CO₂ emitted by fossil fuel combustion with the remaining ~45% removed by the oceans and the terrestrial biosphere.

CO₂ Global Average

The globally averaged CO2 mole fraction in 2012 was 393.1±0.1 ppm. The mean annual increase from 2011 to 2012, 2.2 ppm, is greater than the increase from 2010 to 2011, the average growth rate for the 1990s (~1.5 ppm/yr) and the average growth rate for the past decade (~2.0 ppm/yr).

Global average abundances of the major, well-mixed, long-lived greenhouse gases – carbon dioxide, methane, nitrous oxide, CFC-12 and CFC-11 – from the NOAA global air sampling network are plotted since the beginning of 1979. These gases account for about 96% of the direct radiative forcing by long-lived greenhouse gases since 1750. The remaining 4% is contributed by an assortment of 15 minor halogenated gases including HCFC-22 and HFC-134a. Source: ESRL/NOAA

Methane (CH4) – THe Second Major Contributor

Methane contributes ~18% to radiative forcing by LLGHGs. Approximately 40% of methane is emitted into the atmosphere by natural sources (e.g., wetlands and termites), and about 60% comes from anthropogenic sources (e.g., ruminants, rice agriculture, fossil fuel exploitation, landfills and biomass burning). Atmospheric CH₄ reached 260% of the pre-industrial level (~700 ppb) due to increased emissions from anthropogenic sources. Globally averaged CH₄ reached a new high of 1819 ± 1 ppb in 2012, an increase of 6 ppb with respect to the previous year (Figure 4). The growth rate of CH₄ decreased from ~13 ppb/yr during the early 1980s to near zero during 1999-2006. Since 2007, atmospheric CH₄ has been increasing again due to increased emissions in the tropical and mid-latitude
Northern Hemisphere. The attribution of this increase to anthropogenic and natural sources is difficult because the current network is insufficient to characterize emissions by region and source process.

Nitrous oxide (N₂O )

Nitrous oxide contributes ~6% to radiative forcing by LLGHGs. It is the third most important contributor to the combined forcing. N₂O is emitted into the atmosphere from both natural (about 60%) and anthropogenic sources (approximately 40%), including oceans, soil, biomass burning, fertilizer use, and various industrial processes. The globally averaged N₂O mole fraction in 2012 reached 325.1 ±0.1 ppb, which is 0.9 ppb above the previous year and 120% of the pre-industrial level (270 ppb). The annual increase from 2011 to 2012 is greater than the mean growth rate over the past 10 years (0.80 ppb/yr).

Radiative forcing, relative to 1750, of all the long-lived greenhouse gases. The NOAA Annual Greenhouse Gas Index (AGGI), which is indexed to 1 for the year 1990, is shown on the right axis.  Of the five long-lived greenhouse gases that contribute 96% to radiative climate forcing, CO₂ and N₂O are the only ones that continue to increase at a regular rate. Radiative forcing from CH₄ increased from 2007 to 2012 after remaining nearly constant from 1999 to 2006. While the radiative forcing of the long-lived, well-mixed greenhouse gases increased 32% from 1990 to 2012 (by ~0.69 watts m^-2), CO₂ has accounted for nearly 80% of this increase (~0.55 watts m^-2). Source: ESRL/NOAA

Recent Global CO₂

• August 2013:     393.11 ppm
• August 2012:     389.82 ppm

Up-to-date weekly average CO₂ at Mauna Loa

• Week beginning on October 27, 2013:     394.20 ppm
• Weekly value from 1 year ago:     391.32 ppm
• Weekly value from 10 years ago:     373.39 ppm

Related Links

• Weekly Average CO2 at Mauna Loa Tops 400ppm June 4, 2013
• CO2 Tops 400ppm at Mauna Loa as Forecast May 11, 2013
• Sudden Surges in Atmospheric CO2: FIRE-EARTH Forecast July 23, 2013
• 400 PPM April 3, 2013

Arctic Ocean Seafloor Methane Venting

Who’s afraid of seafloor methane emissions?

National Science Foundation: Public Release

Methane releases from Arctic shelf may be much larger and faster than anticipated

Thawing by climate change of subsea layer of permafrost may release stores of underlying, seabed methane

A section of the Arctic Ocean seafloor that holds vast stores of frozen methane is showing signs of instability and widespread venting of the powerful greenhouse gas, according to the findings of an international research team led by University of Alaska Fairbanks scientists Natalia Shakhova and Igor Semiletov.

Structure of a gas hydrate block embedded in the sediment of hydrate ridge, off Oregon. GNU Free Documentation license. Details

The research results, published in the March 5 edition of the journal Science, show that the permafrost under the East Siberian Arctic Shelf, long thought to be an impermeable barrier sealing in methane, is perforated and is starting to leak large amounts of methane into the atmosphere. Release of even a fraction of the methane stored in the shelf could trigger abrupt climate warming.

“The amount of methane currently coming out of the East Siberian Arctic Shelf is comparable to the amount coming out of the entire world’s oceans,” said Shakhova, a researcher at UAF’s International Arctic Research Center. “Subsea permafrost is losing its ability to be an impermeable cap.”

Worldwide distribution of confirmed or inferred offshore gas hydrate-bearing sediments. USGS

Methane is a greenhouse gas more than 30 times more potent than carbon dioxide. It is released from previously frozen soils in two ways. When the organic material (which contains carbon) stored in permafrost thaws, it begins to decompose and, under anaerobic conditions, gradually releases methane. Methane can also be stored in the seabed as methane gas or methane hydrates and then released as subsea permafrost thaws. These releases can be larger and more abrupt than those that result from decomposition.

Laptev and East Siberian Seas. Credit: UAF.

The East Siberian Arctic Shelf is a methane-rich area that encompasses more than 2 million square kilometers of seafloor in the Arctic Ocean. It is more than three times as large as the nearby Siberian wetlands, which have been considered the primary Northern Hemisphere source of atmospheric methane. Shakhova’s research results show that the East Siberian Arctic Shelf is already a significant methane source, releasing 7 teragrams of methane yearly, which is as much as is emitted from the rest of the ocean. A teragram is equal to about 1.1 million tons.

“Our concern is that the subsea permafrost has been showing signs of destabilization already,” she said. “If it further destabilizes, the methane emissions may not be teragrams, it would be significantly larger.”

Glacier clathrate hydrate (fire-ice). The indications are that nature has no intention of releasing the “methane burp” gradually—Fire-Earth

Shakhova notes that the Earth’s geological record indicates that atmospheric methane concentrations have varied between about .3 to .4 parts per million during cold periods to .6 to .7 parts per million during warm periods. Current average methane concentrations in the Arctic average about 1.85 parts per million, the highest in 400,000 years, she said. Concentrations above the East Siberian Arctic Shelf are even higher.

The East Siberian Arctic Shelf is a relative frontier in methane studies. The shelf is shallow, 50 meters (164 feet) or less in depth, which means it has been alternately submerged or terrestrial, depending on sea levels throughout Earth’s history. During the Earth’s coldest periods, it is a frozen arctic coastal plain, and does not release methane. As the Earth warms and sea level rises, it is inundated with seawater, which is 12-15 degrees warmer than the average air temperature.

“It was thought that seawater kept the East Siberian Arctic Shelf permafrost frozen,” Shakhova said. “Nobody considered this huge area.”

“This study is a testament to sustained, careful observations and to international cooperation in research,” said Henrietta Edmonds of the National Science Foundation, which partially funded the study. “The Arctic is a difficult place to get to and to work in, but it is important that we do so in order to understand its role in global climate and its response and contribution to ongoing environmental change. It is important to understand the size of the reservoir–the amount of trapped methane that potentially could be released–as well as the processes that have kept it “trapped” and those that control the release. Work like this helps us to understand and document these processes.”

Earlier studies in Siberia focused on methane escaping from thawing terrestrial permafrost. Semiletov’s work during the 1990s showed, among other things, that the amount of methane being emitted from terrestrial sources decreased at higher latitudes. But those studies stopped at the coast. Starting in the fall of 2003, Shakhova, Semiletov and the rest of their team took the studies offshore. From 2003 through 2008, they took annual research cruises throughout the shelf and sampled seawater at various depths and the air 10 meters above the ocean. In September 2006, they flew a helicopter over the same area, taking air samples at up to 2,000 meters (6,562 feet) in the atmosphere. In April 2007, they conducted a winter expedition on the sea ice.

They found that more than 80 percent of the deep water and more than 50 percent of surface water had methane levels more than eight times that of normal seawater. In some areas, the saturation levels reached more than 250 times that of background levels in the summer and 1,400 times higher in the winter. They found corresponding results in the air directly above the ocean surface. Methane levels were elevated overall and the seascape was dotted with more than 100 hotspots. This, combined with winter expedition results that found methane gas trapped under and in the sea ice, showed the team that the methane was not only being dissolved in the water, it was bubbling out into the atmosphere.

These findings were further confirmed when Shakhova and her colleagues sampled methane levels at higher elevations. Methane levels throughout the Arctic are usually 8 to 10 percent higher than the global baseline. When they flew over the shelf, they found methane at levels another 5 to 10 percent higher than the already elevated Arctic levels.

The East Siberian Arctic Shelf, in addition to holding large stores of frozen methane, is more of a concern because it is so shallow. In deep water, methane gas oxidizes into carbon dioxide before it reaches the surface. In the shallows of the East Siberian Arctic Shelf, methane simply doesn’t have enough time to oxidize, which means more of it escapes into the atmosphere. That, combined with the sheer amount of methane in the region, could add a previously uncalculated variable to climate models.

“The release to the atmosphere of only one percent of the methane assumed to be stored in shallow hydrate deposits might alter the current atmospheric burden of methane up to 3 to 4 times,” Shakhova said. “The climatic consequences of this are hard to predict.”

Shakhova, Semiletov and collaborators from 12 institutions in five countries plan to continue their studies in the region, tracking the source of the methane emissions and drilling into the seafloor in an effort to estimate how much methane is stored there.

###

Contact: Dana Cruikshank
dcruiksh@nsf.gov
National Science Foundation

Arctic Tundra 4ºC Hotter Since 1970

Arctic tundra much warmer, darker and more heat absorbent

Parts of Arctic tundra are heating up very rapidly, releasing more greenhouse gases than forecast, accelerating global warming


The Advanced Microwave Scanning Radiometer (AMSR-E), a high-resolution passive microwave Instrument on NASA’s Aqua satellite, shows the state of Arctic sea ice on September 10 in this file image released September 16, 2008.  REUTERS/NASA/Goddard Space Flight Center Scientific Visualization Studio/Handout/Files

Parts of Arctic tundra are heating up very rapidly, releasing more greenhouse gases than forecast and accelerating the rate of global warming, said Professor Greg Henry of the University of British Columbia on July 29, 2009.

Thermokarst ponds and drunken forest, Churchill, Manitoba. The thawing of ice-rich permafrost causes subsidence of the land surface, creating ponds and causing trees to tilt, which is shown in this peatland terrain. [Latitude: 58.665 Longitude: -94.034] Physiographic Region: Shield (Lowlands). Photo: Lynda Dredge. Geological Survey of Canada.

Henry said also said higher temperatures are encouraging the spread of larger plants across the tundra, areas normally covered by small shrubs, grasses and lichen. The denser plant cover indicates that the region is getting darker and therefore absorbing more heat.

Tundra covers about 15 percent of Earth’s surface, making up about 30 percent of Canadian territory, Reuters reported Henry as saying.

Henry said for more than three decades he had measured “a very substantial change” in the tundra,  which has been caused by greater emissions and plant growth.

“Since 1970, he said, temperatures in the tundra region had risen by 1 degree Celsius per decade — equal to the highest rates of warming found anywhere on the planet.” Reuters reported.

Henry said:

We’re finding that the tundra is actually giving off a lot more nitrous oxide and methane than anyone had thought before,” Henry told reporters on a conference call from Resolute in the northern Canadian territory of Nunavut.

We’re really trying to get a handle on this because if (further tests show) that’s true, this actually changes the entire greenhouse gas budget for the North, and that has global implications.

The effects of climate change in Canada’s North and Arctic regions, enhanced  by an overload of greenhouse gases,  are particularly alarming.

“Henry said his research station in Nunavut had recorded record high temperatures virtually every summer since the early 1990s. The warmer temperatures mean plants are growing bigger and faster, while larger species are spreading northward.” Reuters reported.

Henry, who also chairs an international project studying tundra, said:

The tundra is getting a lot weedier all the way around the globe. This has major implications … You’re changing the color of the surface of the earth by making it darker … so the consequence of that is increased warming again.

Most “independent” researchers say the thawing of  permafrost in the Arctic region would release great amounts carbon dioxide and methane into the atmosphere, leading to a faster rate of [exponential] rise in the climate change. Original report by Reuters.

Related Links:

• CO2e [FEWW Links Page]

• Drunken Forest

• Earth’s scars of human destruction visible: astronaut
• STOP Chocking Nature to YOUR Death!
• US Gov Releases Intelligence Images of Arctic Ice
• Reduce Harmful Emissions by Wealthy Individuals
• New York Cognitive Dissonance

• A third of U.S. birds endangered
• Global warming worse than predicted: Surprised?
• Only Zero Emissions Would Avert Dangerous Warming