This year, international delegates gathered in Katowice, Poland for the thirty-second international climate meeting in 40 years. As they dithered over whether they should “welcome” or “note” the 1.5°C pathways report they had commissioned, our world was on pace to set another all-time record of 10.88 billion tonnes of annual carbon emissions. Carbon-dioxide in our atmosphere has reached over 412 parts per million, 47% higher than pre-industrial levels, and higher than any time in the last four million years.
In spite of record increases in solar and wind energy development, human carbon emissions continue to rise because, over the last decade, fossil fuel use has grown ten-times faster than renewable energy use. In spite of good intentions, nothing we have achieved has actually reduced oil, gas, and coal use. Given the slow pace of climate action, some ecologists have wondered if peak oil production might arrive in time to forestall runaway global heating.
Oil industry disinformation has unnecessarily confused the biophysical fact of peak oil. Non-renewable or very-slowly-renewable resources — such as oil and coal — typically exhibit a bell-shaped production curve, with a rise, peak, and decline. Conventional oil from drilled wells appears to have reached its peak. As conventional oil production begins to decline, that process could help reduce carbon emissions. However, of course, there’s a catch.
How peak oil is disguised
Oil companies and oil producing nations will claim that peak oil is not a real phenomenon or will not occur for many decades. To support this opinion, they use deception, re-defining what we once meant by “oil.” In late 2004, conventional oil production — typically from drilled wells — stopped growing and has since been on a long plateau, indicating the natural production peak.
Meanwhile, the alleged “increase” in oil production has been achieved with dirty, marginal, low-net energy grunge petroleum, financed with massive debt, stock scams, and outright Ponzi schemes. The swindle has had a disastrous effect on ecosystems, on our atmosphere, on the world economy.
The following graphic, prepared from US Energy Information Administration data by Art Berman of Labyrinth Consulting, reveals the plateau of conventional oil production since late 2004, and the growth of so-called “unconventional” oil:
Chart by Art Berman, Labyrinth Consulting.
Conventional oil plateau, the top of the bell curve. © Chart by Art Berman, Labyrinth Consulting.
Since 2000, as world traditional oil production stagnated, the amount of “unconventional” oil has tripled, from five to 15 million barrels per day. Ecologists who care about global heating, would rather see all oil production declining, but we should pay special attention to the carbon-intensive unconventional petroleum now being dredged from the Earth with what the industry calls “enhanced oil recovery.”
Destructive methods such as fracking and surface mining, produce low-quality, high-carbon sludge erroneously defined as “oil.” These expensive, energy-intensive processes require so much heat that the net energy delivered to society plummets, while ecological costs sky-rocket.
Net energy is an important piece of the puzzle. To produce a hundred barrels of oil in the 1940s and 50s, during the hay-day of cheap oil, companies could invest about one barrel of energy, a very profitable 100:1 net energy. Ninety-nine percent of the energy produced, could be delivered to society.
An Open-Pit Mine at the Alberta Tar Sand © Greenpeace / E M
An Open-Pit Mine at the Alberta Tar Sand © Greenpeace / E M
Today, in the tar sands or shale oil fracking fields, a hundred barrels of oil requires 25 to 50 barrels of oil-energy to produce a lower quality, dirtier product. Not only is this not very profitable in dollars, the process destroys ecosystems, increases carbon emissions, costs more to refine, is harder to clean up when spilled, discharges toxic effluents, and delivers far less actual energy to society. Tar sands bitumen can be burned for energy, but it is not “oil,” and adding bitumen onto “oil production” is like tacking the chaff onto the wheat harvest, a deception designed to disguise peak conventional oil and forestall the urgent transition to renewable energy.
The dregs of ancient sea-beds
Having burned through the high-quality oil, producers are now scouring and fracking the Earth for the dregs of fossil fuels, the so-called “unconventional oil,” in several forms.
“Heavy oils,” are dense, gooey, asphaltic, deposits of organic matter locked in rock and sand. The large molecules incorporate sulfur, metals, waxes, and carbon residue that must be removed, adding to expense and carbon emissions. Bitumen, too thick to move through a pipe without dilution by lighter oil, contains known carcinogens. When spilled from pipelines and ships, the insoluble bitumen sinks to the bottom of rivers, lakes, oceans, and aquifers, requiring massive clean-up costs, and causing decades-long ecological damage. the bitumen requires immense temperatures to convert to fuel, thus more energy lost and carbon emitted.
“Synthetic liquids” include gas-to-liquid (GTL), coal-to-liquid (CTL), and Natural gas plant liquids (NGPL). The infamous IB Farben chemical company introduced a CTL process in the 1930s to provide energy-strapped Nazi Germany with fuel for warfare. The conversion requires substantial heat, high water consumption, toxic waste water, releases significant CO2 emissions, and discharges carcinogens into air, land, and water. Most of these synthetic liquids contain only about 60% of the energy content in conventional crude oil, with twice the ecological impact.
© Sean Gardner / Greenpeace
Oil Rig in the Gulf of Mexico © Sean Gardner / Greenpeace
“Deep Water” oil fields drill in up to three kilometers of ocean water. The Gulf of Mexico contains more than 3,400 deep water wells and the precarious technology is now spreading into the Mediterranean, along the coast of East Africa, and into the Arctic. In 2010, British Petroleum’s deepwater oil rig exploded, spilled some 250 million gallons of oil into the Gulf of Mexico (some analysts believe much more), killed 11 people, some 82,000 birds, 6,000 sea turtles, and 26,000 marine mammals. In 1991, Shell Oil attempted to dump their deepwater Brent Spar, filled with toxic waste oil, into the North Sea, a plan halted by an historic Greenpeace action. In 2012, Shell’s Kulluk deep water drilling rig ran aground off Kodiak Island. There exists no adequate response to oil spills in the Arctic; relief wells are difficult to drill and oil recovery is nearly impossible in the icy conditions and due to a lack of adequate ships.
“Biofuels” can be useful when produced from waste biomass in small, local applications, but they comprise extremely low-net-energy oils. Making corn ethanol in the US burns about 77% of the energy it provides. Biogas, syngas, ethanol, and biodiesel contain only about 2/3 the energy of conventional gasoline. Carbon dioxide is emitted during both the fermentation and combustion of biofuels. Studies in Brazil and Japan show that biofuel emissions increase air pollution deaths. Commercial biofuels require land for crops, which means a loss of both forest cover and food-agriculture land. According to a University of Minnesota study, to replace 12% of US gasoline consumption with ethanol would require 100% of US corn crops.
Fracking Ponzi scheme
Finally, we come to what the oil industry calls “Tight oil and gas,” locked in dense formations of shale, requiring heat, pressure, and chemicals — fracking — to break apart the rock and allow the oil or gas to flow. Petroleum fuels can be produced from fracking, but the ecological and financial costs are monumental.
A fracking well typically requires some 8 million gallons of water, 40,000 gallons of toxic chemicals, and results in increased carbon emissions. A study at the Colorado School of Public Health, found that oil and gas fracking released toxic toluene, ethyl benzene, nitrogen oxides, carbon monoxide, formaldehyde, and metals. Exposure to these pollutants are known to cause cancer, organ damage, nervous system disorders, lung disease, birth defects, and death.
Fracking requires so much energy, water, and material that production costs soar. Companies involved in the so-called “US shale-oil boom” have borrowed and lost billions of dollars. According to the Wall Street Journal, since 2010, the US shale industry has spent $265 billion more than it has generated. Nevertheless, insiders make money because the industry works as a giant Ponzi scheme, in which schemers profit from stock scams, leaving later investors with bankrupt companies and depleted oil fields.
Since 1980, the US economy and "oil boom" has been fueled by debt. Chart by Pedro Pietro with data from World Bank.
Since 1980, the US economy and “oil boom” has been fueled by debt. Chart by Pedro Pietro with data from World Bank.
According to a review by Canadian petroleum geologist David Hughes, total US shale oil production peaked in 2004 and has been in decline since. Most of the shale oil comes from two fields in the Permian Basin, in Texas, which have declined by about 80% over 3 years, while incurring a $40 billion cash flow deficit. The Texas Eagle Ford fields peaked in 2015, and companies are spending $4 billion/year on new wells for declining production.
To keep up production, Hughes points out, fracking companies claim they will drill some 1.29 million tight gas wells between now and 2050. At $6 million per well, this amounts to $7.7 trillion. “The industry’s long-term forecasts are unrealistic,” says Hughes, “and likely more designed to maintain share price than to provide a sound energy policy.”
We can, of course, imagine how $7.7 trillion might help finance a transition to renewable energy and lower energy consumption. “Climate change and peak oil are two ends of the same snake,” writes energy analyst Mary Logan in “Thinking Like a System about Climate Science.” Climate change, she believes, is “a proxy for our oil addiction problem,” and the root cause is our “flywheel economy,” that cannot slow down. Oil barons, bankers, and stock swindlers appear willing to extract dirty, carbon-intensive, low-quality fossil fuels to cover up the imminent reality of peak conventional oil, while ignoring the climate crisis. These tycoons and willing governments squeeze marginal profits from their dirty oil rather than help lead humanity into a reasonable transition to a lower-energy and renewable energy future.
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References and Links:
CO2 concentrations higher than any time in last 4 million years: “Analysis of the Temperature Oscillations in Geological Eras,” C.R. Scotese, 2002; “Earth’s Climate Past and Future,” W.F. Ruddiman, 2001; and “Marked decline in Atmospheric Carbon Dioxide Concentrations During the Paleocene, Mark Pagani, et al., Science, v. 309, No. 5734, 22 July 2005; data graph, updated 2008, from “Historical Carbon Dioxide Levels,” Dr. Vincent Gray, Watts Up With That, Anthony Watts, 2013.
“Thinking Like a System about Climate Science,” Mary Logan, A Prosperous Way Down, 2012.
“Unconventional Oil & Gas Production,” International Energy Agency, IEA.
“World Energy Outlook, 2018, IEA.
“The International Energy Agency recognizes the arrival of Peak Oil,” The Oil Crash, 2010
“Peak Oil: IEA Knew It Long Ago,” Colin Campbell, The Oil Drum, 2009
“Ethanol production, purification, and analysis techniques: a review, Shinnosuke Onuki, Jacek A. Koziel, et al., Iowa State University, 2008. Agricultural and Biosystems Engineering Conference Proceedings and Presentations. 
“Climate change and health costs of air emissions from biofuels and gasoline,” Jason Hill, et al., Sustainability Science, US National Academy of Sciences, 2009.
“Variations in the greenhouse-gas emissions and irrigated water use of U.S. corn production. University of Minnesota, Proceedings of the National Academy of Sciences, 2017.
“Impacts of Ethanol Policy on Corn Prices,” Nicole Condon, Heather Klemick, and Ann Wolverton; National Center for Environmental Economics, US EPA.
“10 Reasons Why Arctic Oil Drilling Is a Really Bad, Stupid Idea,” by Ben Stewart, Greenpeace, 2012.
“Brent Spar: The sea is not a dustbin,” Rex Weyler, Greenpeace, 2016
“Modeling Oil Depletion Using EIA Data,” Nate Hagens, Oil Drum, 2006
“Human Health Risk Assessment of Air Emissions from Development of Unconventional Natural Gas Resources,” L. McKenzi, et al., Science of the Total Environment,424:79-87, 2012.
“Impacts of Gas Drilling on Animal and Human Health,” M. Bamberger, R. Oswald, New Solutions: A Journal of Environmental and Occupational Health, 22(1): 51-77, 2012.
Potential Health and Environmental Effects of Hydrofracking in the Williston Basin, Montana, Joe Hoffman; Department of Earth Sciences, Montana State University, 2012
“Natural Gas Operations from a Public Health Perspective,” T. Colborn, et al., Human and Ecological Risk Assessment, 17(5):1039-1056, 2012. 
“The Need for Strong Caveats on Proved Oil Reserves, and R/P Ratios” R.W. Bentley, The Oil Age, pdf, September, 2018.
“Extrapolation of oil past production to forecast future production in barrels,” Jean Laherrère, pdf, 31 August 2018.
“Shale Reality Check”, David Hughes, Post Carbon Institute, 2018
“Drilling Deeper: A Reality Check on U.S. Government Forecasts for a Lasting Tight Oil & Shale Gas Boom,” Dave Hughes, Post Carbon Institute, 2014.
“Gloomy Prospects in IEA’s Latest World Energy Outlook: Renewables growth won’t deliver a climate cure,” Jason Deign, Green Tech Media, 13, 2018.
“Flip This Well: How Fracking Company CEOs Get Rich While Losing Billions, Justin Mikulka, Desmog, May 29, 2018