A New California Oil Boom? Drilling the Monterey Shale
Part 1: Distracted by Fracking?
By Robert CollierEnergy & Climate
This is the first installment of a special series looking at the potential climate and public health implications of a boom in Monterey Shale production.
Over the past few years, the United States has found itself in the midst of a major boom in oil and gas production. Rapid expansion in the use of a drilling technique called hydraulic fracturing, or “fracking,” has opened up previously unreachable pockets of oil and gas, and returned the U.S. to its historic position as a major global producer of these fossil fuels.
Over the past few years, the United States has found itself in the midst of a major boom in oil and gas production. Rapid expansion in the use of a drilling technique called hydraulic fracturing, or “fracking,” has opened up previously unreachable pockets of oil and gas, and returned the U.S. to its historic position as a major global producer of these fossil fuels.
And it seems the boom may be coming to California. Once a leading producer of oil in the U.S., California’s production has fallen off dramatically over the years as oil fields age and are depleted. But could America’s fracking-fueled oil resurgence breach the oil fields of California, particularly in the relatively untapped Monterey Shale? Could a fracking revolution once again make California a leading producer of domestic oil? And if so, what might this mean for the state’s aggressive clean energy and climate goals?
Given the dramatic examples of North Dakota, Texas and Pennsylvania, where widespread use of fracking has helped oil and gas production soar, it might seem inevitable for California to be the next boom state. The Monterey Shale formation, which runs from north-central through southern California, has billions of barrels of oil locked away in its underground nooks and crannies. Petroleum geologists and engineers, always searching for the next strike, are feverishly seeking the technological fix to unlock those riches.
Politically, it’s the same fight as elsewhere – environmental regulations have been drafted, legislation written and fought over, Hollywood films made, coalitions pro and con organized -- all focused on the potential benefits, and threats, of widespread fracking.
Given the dramatic examples of North Dakota, Texas and Pennsylvania, where widespread use of fracking has helped oil and gas production soar, it might seem inevitable for California to be the next boom state. The Monterey Shale formation, which runs from north-central through southern California, has billions of barrels of oil locked away in its underground nooks and crannies. Petroleum geologists and engineers, always searching for the next strike, are feverishly seeking the technological fix to unlock those riches.
Politically, it’s the same fight as elsewhere – environmental regulations have been drafted, legislation written and fought over, Hollywood films made, coalitions pro and con organized -- all focused on the potential benefits, and threats, of widespread fracking.
A “sleeper” oil field technology?
But in California, at least, the obsession with fracking may be misplaced. In recent months, policymakers have begun to realize that the debate about fracking may be a distraction from the technology that’s the more likely candidate for tapping the Monterey Shale: A technique, already widely in use in the oil industry, known as “acidizing.”
It’s not widely discussed in laymen’s circles, but for some time oil companies have found acidizing more effective in the Monterey Shale than fracking.
Acidizing, also referred to as “matrix acidization,” typically involves the injection of high volumes of hydrofluoric acid, a powerful solvent, (abbreviated as “HF”) into the oil well to dissolve rock deep underground and allow oil to flow up through the well. Conventional fracking, in which water and other chemicals are pumped at high pressure to create fissures in the rocks, reportedly does not work well in many parts of the Monterey Shale – a rock formation known for its complexity and low permeability, which makes fracking less effective.
It’s not widely discussed in laymen’s circles, but for some time oil companies have found acidizing more effective in the Monterey Shale than fracking.
Acidizing, also referred to as “matrix acidization,” typically involves the injection of high volumes of hydrofluoric acid, a powerful solvent, (abbreviated as “HF”) into the oil well to dissolve rock deep underground and allow oil to flow up through the well. Conventional fracking, in which water and other chemicals are pumped at high pressure to create fissures in the rocks, reportedly does not work well in many parts of the Monterey Shale – a rock formation known for its complexity and low permeability, which makes fracking less effective.
A critical tool – but mistakes can be deadly
In the oil patch, hydrofluoric acid can therefore be a critical tool. But HF is also one of the most dangerous of all fluids used in oil production – and indeed in any industrial process. It is used in many oil refineries nationwide to help turn oil into gasoline and other products; while accidents are rare, they can be fatal.
Currently, large amounts of HF (precise volumes are an industry secret) are routinely trucked around California and mixed at oilfields. Critics call it a disaster waiting to happen. There have been minor HF leaks in other states, though no major catastrophes in the U.S. such as a recent HF tragedy in Korea.
Yet acidizing remains almost totally unregulated. State and federal rules currently being drafted in Sacramento and Washington, DC, make no mention of acidizing. An exception is legislation currently under debate in Sacramento, authored by Sen. Fran Pavley, D-Agoura Hills, who has spearheaded much of the state’s climate laws in recent years.
Whether California regulates acidizing may have national and global implications. Although the state appears to be the first to do major experimentation with high-volume acidizing, the rapid expansion of unconventional oil technologies in shale formations in other states suggests that oil companies might try to export any successful California experiments to other locations.
Currently, large amounts of HF (precise volumes are an industry secret) are routinely trucked around California and mixed at oilfields. Critics call it a disaster waiting to happen. There have been minor HF leaks in other states, though no major catastrophes in the U.S. such as a recent HF tragedy in Korea.
Yet acidizing remains almost totally unregulated. State and federal rules currently being drafted in Sacramento and Washington, DC, make no mention of acidizing. An exception is legislation currently under debate in Sacramento, authored by Sen. Fran Pavley, D-Agoura Hills, who has spearheaded much of the state’s climate laws in recent years.
Whether California regulates acidizing may have national and global implications. Although the state appears to be the first to do major experimentation with high-volume acidizing, the rapid expansion of unconventional oil technologies in shale formations in other states suggests that oil companies might try to export any successful California experiments to other locations.
Industry abuzz, but details are secret
Hydrofluoric acid is typically mixed with water and other chemicals, with HF concentration normally less than 9 percent. However, oil company executives have said they are experimenting in California with higher concentrations and pressures, testing the boundaries of geology, engineering -- and safety.
Exactly how high those experimental concentrations and pressures are is a closely held secret. At a May 2013 industry conference in Bakersfield, executives in attendance speculated nervously about what their competitors were doing. Each company was clearly working on its own secret formula, trying to find its own recipe for success.
The buzz among conference attendees was about Occidental Petroleum, which had demonstrated much success with HF acidizing at its Elk Hills field.
“As you have seen here, companies are experimenting widely with acidizing,” said Maysam Pournik, a geology professor at the University of Oklahoma who spoke at the event.[1] “Nobody is saying exactly what they are doing, because the Monterey Shale is extremely complex, and companies need to try new methods at the limits.”
Some executives said they believe their competitors were experimenting with HF concentrations as high as 30 percent. But others downplayed such talk.
“If you use that much HF, you will melt your well casings,” said Paul Gagnon, senior vice president of Central Resources, a Denver-based oil firm. “It’s not doable.”[2] Left unsaid was the environmental danger – that HF could breach the double or triple steel walls of the well casings and enter the surrounding water table, putting local water supplies at risk.
Exactly how high those experimental concentrations and pressures are is a closely held secret. At a May 2013 industry conference in Bakersfield, executives in attendance speculated nervously about what their competitors were doing. Each company was clearly working on its own secret formula, trying to find its own recipe for success.
The buzz among conference attendees was about Occidental Petroleum, which had demonstrated much success with HF acidizing at its Elk Hills field.
“As you have seen here, companies are experimenting widely with acidizing,” said Maysam Pournik, a geology professor at the University of Oklahoma who spoke at the event.[1] “Nobody is saying exactly what they are doing, because the Monterey Shale is extremely complex, and companies need to try new methods at the limits.”
Some executives said they believe their competitors were experimenting with HF concentrations as high as 30 percent. But others downplayed such talk.
“If you use that much HF, you will melt your well casings,” said Paul Gagnon, senior vice president of Central Resources, a Denver-based oil firm. “It’s not doable.”[2] Left unsaid was the environmental danger – that HF could breach the double or triple steel walls of the well casings and enter the surrounding water table, putting local water supplies at risk.
A recognized human hazard
HF is commonly used in oil refineries, where it serves as a catalyst to produce high-octane gasoline. It is one of the most hazardous industrial chemicals in use, according to the U.S. Centers for Disease Control. HF can cause severe burns to skin and eyes, and can damage lungs in ways that may not be immediately painful or visible. Overexposure causes painful, deep-seated and slow-healing burns and ulcers. If absorbed through the skin in even minute amounts and left untreated, HF may cause death.
Tupper Hull: The oil industry has long known about the Monterey Shale.....
Tupper Hull: The oil industry has long known about the Monterey Shale.....
The dangers of HF are compounded by its extreme volatility at relatively low temperatures. If temperatures are cool, HF is a liquid. But at 67.1 degrees F, HF boils into a dense vapor cloud that, if released into the open, does not dissipate, hovers near the ground and can travel great distances – meaning the risks of a spill to nearby population centers are significant.
The National Fire Protection Association system rates hydrofluoric acid in the most dangerous category of hazardous materials. Hydrofluoric acid also is recognized on the Superfund list of Extremely Hazardous Substances. As a powerful corrosive, it dissolves nearly anything – research on matrix acidizing lists “corrosion” as one of the primary challenges.[3]
There appears to be no research or other publicly available information about HF’s use in oil and gas production or its potential effects on groundwater supplies. But the risks are clear.
Next in the series: The most dangerous chemical you’ve never heard of
[1] Interview with author at “Tight Oil Reservoirs California” conference, Bakersfield, May 30, 2013.
[2] Interview with author at “Tight Oil Reservoirs California” conference, Bakersfield, May 29, 2013.
[3] http://www.jmaterenvironsci.com/Document/vol3/vol3_N5/87-JMES-234-2012-Puthalath-review.pdf
http://www.onepetro.org/mslib/servlet/onepetropreview?id=NACE-03121
http://www.onepetro.org/mslib/servlet/onepetropreview?id=00038594
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