Risky Hydraulic Fracturing? Report on Fracking, good article

According to scientific research, the environmental costs are real ...

"According to scientific research, the environmental costs are real but rare."

Editor’s Note: This is the first in a two-part series on the risks associated with hydraulic fracturing and how policymakers can respond to them.

The nation is experiencing a natural gas and oil boom due in no small part to hydraulic fracturing. In many states, hydraulic fracturing has been the driver behind economic growth. But the process is among the environmentalist movement’s top targets. However, the scientific research on the water-related concerns associated with fracturing suggests environmentalists’ concerns are overblown: although the risks are real, their occurrences are rare.

Although developed in the 1940s, only recently has hydraulic fracturing become widely used as a result of advances in the process. It is important to note that drilling a hydraulically fractured well is basically identical to drilling a conventional well. The main difference stems from the horizontal drilling component coupled with the fracturing process.

  Illustration by Barbara Kelley

After drilling the vertical well and encasing the pipe in cement, approximately 500 feet above the intended lateral zone, a special drill bit is inserted into the well that drills at a sloping angle eventually leveling out at a depth as much as a mile under the surface to drill horizontally. Cement is pumped between the piping and the shale formation to seal the well.

The targeted lateral zone is prepped for the hydraulic fracturing process using an electrified perforation gun to perforate the pipe, cement casing, and shale formation. Because the perforations are not large enough to allow hydrocarbons to flow, a special fluid made of approximately 99 percent water and 1 percent sand and additives is pumped into the well to widen and hold open the cracks in the shale formation.

The injection part of the hydraulic fracturing process is what has triggered most of the environmental concerns, although some local communities object to the growth itself because it can drive up housing prices, increase traffic, and put pressure on governmental infrastructure such as roads and schools.

Of the environmental concerns, three issues stand out—water use, water contamination, and induced seismic activity. There is little doubt that the risks associated with these concerns are real; however, research shows they are less of a concern than opponents would have the public believe.

Because hydraulic fracturing uses approximately two to five million gallons of water per well, much of which stays far below the earth’s surface, many say the process will deplete water supplies. True, as much as 80 percent of the water pumped into a hydraulic fracturing well is removed from surface or groundwater supplies, but in terms of the hydrological cycle, this ignores the fact that burning methane (CH4) produces carbon dioxide and water. Assume that a hydraulic fracturing well uses five million gallons of water, leaves 80 percent underground, and produces 2 billion cubic feet of gas over its 10 year life span. Burning the gas will replace the four million gallons left underground in 6 months and produce 11 million gallons over 10 years. Of course, the “new” water in the hydrological cycle is in a different place and form, e.g. in the atmosphere, but in total, hydraulic fracturing adds water to the hydrological cycle.

Nonetheless, five million gallons of water per well is a lot, especially if it is in locations where fresh water is in short supply. Indeed, 47 percent of the water used for hydraulic fracturing occurs in areas deemed “high or extremely high water stress” zones. However, let’s putt the water use in perspective. New York City consumes five million gallons of water in just over six minutes; a single 1,000 megawatt coal-fired power plant uses five million gallons of water in just under 11 hours; and an irrigated golf course uses five million gallons of water in 23 days. Five million gallons of water are needed to produce 64 tons of steel, and 40 American households use five million gallons for annual indoor uses alone.The Susquehanna River Basin Commission concluded that water use in the Marcellus Shale in total “represents a little more than half of the amount currently used consumptively by the recreation sector (golf courses, water parks, ski resorts, etc.)”

Of course, in the arid western states experiencing pressure on the demand for residential, commercial, and agricultural water, adding hydraulic fracturing demands is non-trivial. Balancing these demands, however, need not require banning hydraulic fracturing. The solution is to develop well-functioning water markets to ensure water rights are fully defined and transferable; price signals would lead to efficient water use.

In addition to water scarcity, there are claims that the hydraulic fracturing process will contaminate groundwater. One alleged source of contamination is the fracturing fluids, but there is little evidence to support this allegation. Indeed, studies from Duke University, University of Texas at Austin, Massachusetts Institute of Technology (MIT), and even the U.S. Environmental Protection Agency find no evidence of fracturing fluid contamination in water sources.

The other potential source of groundwater contamination is methane leakage, and there is some evidence of methane in water supplies nearby hydraulic fracturing sites. Although the Duke University study found methane levels about 17 times greater than expected, the University of Texas at Austin report suggests that the higher methane levels may not be due to hydraulic fracturing, but are naturally occurring in the water sources. The MIT report concludes that even if methane contamination from hydraulic fracturing is occurring, it is because of poor well design and preparation, both of which can be and are easily remedied. Again, while there is a risk of methane contamination, the issue can be resolved by properly instilling market risk assessment, i.e. increasing the price of risky behavior relative to thoughtful risk control.

Finally, there is concern that hydraulic fracturing will induce seismic activity. Initially, many thought that induced earthquakes were the result of the fracturing process itself, but if there is a seismic threat, it results from the disposal of produced water—excess fracturing fluid returning to the surface—and/or the flowback—naturally occurring water that flows out of the well following fracturing. If improperly disposed of, this water can lubricate subterranean rock formations, causing them to shift.

Even if slippage can theoretically cause earthquakes, the likelihood that they would be significant is trivial. Research conducted by Arthur McGarr of the U.S. Geological Survey shows that the magnitude of an earthquake has a proportional relationship to the volume of fluid disposed. Roughly 10,000 cubic meters of fluid could yield a maximum magnitude of 3.3, increasing by approximately 0.4 with each doubling of the fluid. By McGarr’s calculations, five million gallons of water would generate, at most, a 3.7 magnitude earthquake—and remember, not all of the five million gallons returns to the surface.

According to the U.S. Geological Survey, such an earthquake would be “felt only by a person at rest…especially on upper floors of buildings. Many people [would] not recognize it as an earthquake. Standing motor cars may rock slightly...similar to the passing of a truck.” Michigan Technological University classifies a 3.7 magnitude as a minor earthquake and estimates that approximately 30,000 of this magnitude occur naturally every year. Again, while a risk, draconian measures like banning or moratoriums are unnecessary given the minimal intensity. Efficient market risk control would be able to prevent improper water disposal mitigating such concerns.

Whatever the risks of hydraulic fracturing, they must be weighed against the benefits. When the Great Recession hit the United States and doubled unemployment rates, one unlikely state—North Dakota—largely escaped the downturn. North Dakota’s unemployment rate only jumped from 3 percent to just over 4 percent between December 2007 and June 2009. The main reason for North Dakota’s resilience was the state’s oil and gas production, which grew steadily during this period. In December 2007, average daily oil and gas production was 136,021 barrels. By June 2009, the average daily production jumped 58 percent to 215,073 barrels. Behind this explosion of oil and gas production was (and continues to be) the hydraulic fracturing of the Bakken shale play.

And the benefits are not confined to North Dakota. A study by IHS Global Insight found that by 2020 hydraulic fracturing production could add an additional $417 billion to the national economy and employ almost three million people.

Good environmental risk analysis asks several questions. What (if any) is the environmental problem? How does it compare to the problems arising from alternative means of energy production? And how can the risks be mitigated? All forms energy resource extraction and production, even so-called green energy has its risks. For instance, a giant solar powered “plant” in California uses 350,000 mirrors to focus the sun’s heat on boilers atop a tower to create air temperatures of 1,000 degrees Fahrenheit. During the testing phase, workers found dozens of dead birds, from peregrine falcons to sparrows, scattered around the site.

The data on hydraulic fracturing suggest that its risks are rare, but even rare risks need to be addressed. Addressing them, however, does not require oppressive regulation or production moratoriums. It requires balancing the risks against the benefits and getting the incentives right so that those making decisions are accountable, the topic of our follow-up article.


Terry Anderson is the John and Jean De Nault Senior Fellow at the Hoover Institution and the executive director of PERC (the Property and Environment Research Center), a think tank in Bozeman, Montana, that focuses on market solutions to environmental problems. His research helped launch the idea of free-market environmentalism and has prompted public debate over the proper role of government in managing natural resources. He was the cochair of Hoover's Property Rights, Freedom, and Prosperity Task Force.


Carson Bruno is a research fellow at the Hoover Institution who primarily studies California public policy, electoral politics, and public opinion, with a focus on the future of the California Republican Party. Carson also explores domestic economic policy, tax policy, and the intersection of energy and environmental policy. His central interest is in developing market-efficient policies that complement California public opinion and spur economic growth, advance personal liberty, and improve economic mobility within the state. Carson’s examination of national policy largely focuses on its effect on state policy-making decisions. Before joining the Hoover Institution, Carson structured tax-exempt and taxable municipal bond issuances as a public finance investment banker, which gave him an in-depth look at state and local fiscal policy decisions.

He received his master’s degree in public policy with honors from Pepperdine University, specializing in economics and American politics. He has a BS in accounting and business management, with special attainments in commerce, from Washington and Lee University.


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nice post.

as to the big picture, it's generally spot-on and laudably it takes a neutral, objective journalistic posture (imo,rare inre; the subject addressed).

however, it contains several small errors which i won't belabor in this post; after all, they're minor.

i've been griping for a long while about objective industry related news stories, not the other sort of which is unfortunately way more common. 

journalists go to journalism school. there, i guess, they learn the five 'w's': who, what, when, where and why. the skills they absorb in school don't provide them with any basis in knowledge as to any story they may elect to cover, other than, let's say, one about journalism school.

my point here is that we'd all be well-served if there was someplace for journalists to get their industry stories fact checked before turning them in for publication.

the guys on the other side of things are always going to be looking for opportunities to poke holes in any story not hewing to their party line. why give them the ammo even if the inaccuracies are almost innocuous? after all, we all know how they'll endeavor to make a mountain out of a molehill.

i have absolutely no idea as to how to forward/accomplish the thing i suggest, above. i know as much about journalism as i do about theoretical particle physics.

maybe, there's someone(s) on the board that's worked in that business or knows someone that has.

p.s. again, nice post. i'm surely not damning it with faint praise. rather, i know the other side and we can't afford to give them an inch.

You take a 50 caliber rifle and shoot it into a sand pile and you can probably find the somewhat intact bullet. You shoot the same into Mount Rushmore and the impact will probably destroy the bullet fragmenting it into a million pieces. My limited knowledge of science points me to think that a shock wave from an earthquake travels better and faster through solid rock. Rock underground that has been turned to rubble by frac jobs, so it would seem to me that it would be less conductive for shock waves from earthquakes. Maybe Jay or one of the other Geologists on GHS may be more qualified to answer, as to my thoughts.

I get the Energy in Depth emails and they just had a great response to the controversy and a NEW (but not improved) methane study from Cornell University. Longtime readers of GHS will remember their studies and the problems in them. We cannot ignore these studies. Lots of policy makers are being influenced by them. This article is a good response to the more recent one ...

Five Facts about Ingraffea and Howarth’s Latest Methane Study
   Posted by: Katie Brown
Researcher // Washington, D.C.
April. 15, 2014

A new study on methane was published this week, arguing that emissions from seven well pads emit methane “2 to 3 orders of magnitude greater than US Environmental Protection Agency estimates” during the drilling phase of a well. Unsurprisingly, several news outlets put out the expected headlines portending the usual doom. Greenwire proclaims: “Significant methane leaks found from wells still in drilling process.” The LA Times put it this way: “EPA drastically underestimates methane released at drilling sites.”

That all sounds quite serious, until you realize who the authors of the study are: Anthony Ingraffea and Robert Howarth. It’s no secret that this team of activists wants to ban hydraulic fracturing, so it’s also not surprising that they arrived at a conclusion to advance that cause. If you need a refresher, Ingraffea is the president of Physicians Scientists & Engineers for Healthy Energy, an organization that is not only funded by the Park Foundation, but which has taken institutional stances against fracking (Ingraffea actually listed PSEHE ahead of his Cornell affiliation for the study’s author page). In 2012, Howarth signed a “pledge of resistance” to hydraulic fracturing, joining Bill McKibben, Josh Fox, Jakob Dylan, and other “scientists.”

Many of the news reports on the study omitted those details entirely, which is probably what they preferred.

As with their previous research, this latest paper also contains a number of glaring flaws, ranging from small sample sizes to a curious disregard of established climate science. Here are five things to know about their latest study:

Fact #1: Researchers specifically target high emission areas, admit little to no emissions from other well pads

The report states,

“An instrumented aircraft platform was used to identify large sources of methane and quantify emission rates in southwestern PA in June 2012.” (p. 1; emphasis added)

If they were using an aircraft to locate areas with higher methane readings, then why is it “news” that they found high methane readings? Even worse is the researchers’ acknowledgment that the well sites they studied were outliers: The study is clear that the researchers did not detect high emissions in any other well pads other than the seven they focused on; therefore, these readings cannot be taken as representative of Marcellus development as a whole:

“Although we only quantitatively sampled pads where we saw significant enhancement above the background, it is important to note that we could detect little to no emission from many other pads, particularly in the region north of the OSA, from Washington north to Pittsburgh. Thus, we do not intend for our regional flux estimate to be taken as necessarily representative of the Marcellus as a whole but only for the region defined as the OSA for these days.” (p. 3; emphasis added).

In Washington and Allegheny Counties – which include Washington and Pittsburgh, respectively – there are over 800 wells. Yet, the researchers detected little to no emissions from any of those, save for just seven well pads. Undoubtedly, leading with that fact would not have furthered the notion that methane leaks are out of control, so it was buried.

Fact #2: Ingraffea and Howarth use modeling exercises instead of direct measurements

One of the biggest flaws of the report is that it relies on data gathered in just four flights over only two days in southwestern Pennsylvania. Here’s how the researchers characterize their method:

“Here we use an aircraft-based approach that enables sampling of methane emissions between the regional and component level scales and can identify plumes from single well pads, groups of well pads, and larger regional scales, giving more information as to the specific CH4 emission sources. We implemented three types of flights over 2 d in June 2012 […] We show that the methane emission flux from the drilling phase of operation can be 2 to 3 orders of magnitude greater than inventory estimates, providing an example and improved understanding of the differences between observed data and bottom-up inventories.” (p. 2)

In other words, the researchers are capturing methane data, and then running modeling exercises to determine the source. That’s a well-understood method of gathering emissions data, but as the report essentially admits, it is also rife with uncertainty:

“In the region between Washington, PA and south to the border of WV we observed multiple high concentration methane plumes and investigated areas where initial observations revealed well pads with potentially high methane emission rates. The high density of pads in the region and the prevailing wind direction (SW) during the time of measurement combined to make plume attribution to single pads difficult. (p. 3; emphasis added).

Contrast this methodology with direct measurements, which have shown that methane emissions are far below what alarmists have claimed. The University of Texas/Environmental Defense Fund study from last fall – which took the first direct measurements of methane from production sites – looked at 190 natural gas production sites, finding that total annual methane emissions are “comparable” to EPA’s estimates. It suggests a leakage rate of only about 1.5 percent, which is far below the threshold where natural gas would presumably lose its greenhouse gas benefits.

So, essentially, we are comparing direct measurements at the source of nearly 200 wells (UT/EDF, 2013) against a flyover of a handful of wells in one section of one state (Ingraffea/Howarth, 2014) – and most of the wells examined in the latter, it’s worth repeating, revealed little to no emissions, although they were largely ignored.

Fact #3: Ingraffea blasted previous research based on small sample size, but his latest work examined far fewer sites

When the University of Texas last year released what has been called the most comprehensive study on methane to date, Ingraffea said it was “fatally flawed” because it was “based on a small sampling of hydraulically fractured wells which may not adequately represent national oil and gas activity and the variability within and across production basins.”

Yet, this week Ingraffea seems to have no problem releasing a report that studies only seven well pads in one particular region of Pennsylvania.

The news has extrapolated broader meaning (i.e. questioning EPA’s entire Greenhouse Gas Inventory) from Ingraffea’s latest work on methane. But if a study that looked at far more wells was “fatally flawed” based on its sample size, will he be contacting the newspapers and asking for corrections? Something tells us he and his fellow activists won’t.

Fact #4: Funding is provided by the organization that funds Howarth’s Cornell professorship

The acknowledgements section of the report states that funding was provided by the David R. Atkinson Center for a Sustainable Future at Cornell University. Coincidentally, Robert Howarth is “The David R. Atkinson Professor of Ecology and Environmental Biology,” and the Center has long been a supporter of Howarth’s research: For example, they have partnered with the well-known anti-fracking Park Foundation to fund Howarth’s many papers, which also were attacking hydraulic fracturing.

Of course, just because researchers received funding from a particular source does not automatically disqualify their research. But when the funding comes from an organization that also funds one of the most outspoken anti-fracking researchers of the day, it does give one pause. Also of note, while Ingraffea complained loudly that the UT study received some funding from industry, he doesn’t seem too worried about the affiliations of the funders of his own report.

Fact #5: As natural gas production has gone up, methane emissions have fallen dramatically

According to the researchers, “The identification and quantification of methane emissions from natural gas production has become increasingly important owing to the increase in the natural gas component of the energy sector” (p. 1).

As noted above, using direct measurements, the University of Texas/Environmental Defense Fund study found methane leakage rates that were “comparable” to EPA’s estimates from last year. In last year’s report, EPA found that methane emissions from natural gas systems had fallen 10.2 percent since 1990, and emissions from field production had fallen 38 percent since 2006. EPA’s latest Greenhouse Gas Inventory shows that emissions fell 16.9 percent since 1990, with field production emissions falling more than 40 percent since 2006. From 2011 to 2012 (the most recent year for which data were available), methane emissions from natural gas systems declined by 12 percent.

Granted, the “news hook” of this latest research is to suggest that the EPA’s estimates are too low. As such, the EPA’s GHG Inventory cannot in and of itself refute this paper’s allegations. But given the enormous quantity of data that went into EPA’s inventory, versus the handful of sites in this latest paper, it’s worth asking: Can we legitimately question EPA’s data on methane based on outliers, especially when there is plenty of evidence to suggest that EPA’s methane measurements are actually too high?

The timing here is interesting too. The U.N. Intergovernmental Panel on Climate Change (IPCC) recently released its latest report, which specifically credits fracking and natural gas with reducing greenhouse gas emissions:

“A key development since AR4 is the rapid deployment of hydraulic fracturing and horizontal drilling technologies, which has increased and diversified the gas supply… this is an important reason for a reduction of GHG emissions in the United States.” (p. 18)

Which leads to the question: whom should we trust? University researchers who take direct measurements form 190 natural gas sites, the U.S. EPA, and the world’s most prominent climate scientists? Or researchers whose claim to fame has been their advocacy against the very process they are researching?

Complete Post: http://energyindepth.org/national/five-facts-about-ingraffea-and-ho...

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