The environmental costs and benefits of fracking: The state of research
On July 30, 2014, the United States did something that had been legally prohibited for nearly 40 years: It exported domestically produced crude oil. While minor exports had occurred through the years and the July shipment involved some technical sleight-of-hand (the product was classified as lightly refined “condensates”), it was one of the first significant oil shipments since Congress banned exports in the wake of the 1974 oil embargo.
Respecting the law up to now has been easy, given America’s declining domestic oil production and thirst for imported oil — in 2006, the country imported 3.7 trillion barrels. What changed between then and now all comes down to one word: fracking, the popular name for hydraulic fracturing. Combined with horizontal drilling, the technique has powered a boom in U.S. energy production, unlocking substantial petroleum and natural gas deposits trapped in shale formations. A lot of this is good news: U.S. consumers and industry rarely complain when energy prices fall, and reducing imports from unstable parts of the world has considerable appeal. Natural gas also releases half as much carbon dioxide as coal, allowing it to potentially serve as a “bridge fuel” to the cleaner energy supported by the majority of Americans.
Despite these advantages, fracking remains highly controversial, in large part because of the potential damage it poses to human health and the environment. Reports of fracking operations contaminating aquifers are widespread, and research has found indications of higher rates of silicosis among well workers, an increase in congenital defects to children born nearby, and elevated cancer risk due to air pollution. Even earthquakes have been linked to fracking operations. Such concerns have led a number of towns to try to ban the practice, and fracking has become one of the central issues in the 2014 battle for Colorado’s governorship, a crucial swing state.
A 2014 study published in the Annual Reviews of Environment and Resources, “The Environmental Costs and Benefits of Fracking,” provides an overview of state of scientific knowledge on fracking and its impacts. In their introduction, the researchers — based at the Woods Institute for the Environment, Stanford, Duke, Newcastle University, Ohio State, MIT and the University of Colorado — note the complex web of tradeoffs:
Unconventional energy [recovered by hydraulic fracturing] generates income and, done well, can reduce air pollution and even water use compared with other fossil fuels. Alternatively, it could slow the adoption of renewables and, done poorly, release toxic chemicals into water and air. Primary threats to water resources include surface spills, wastewater disposal, and drinking-water contamination through poor well integrity. An increase in volatile organic compounds and air toxics locally are potential health threats, but the switch from coal to natural gas for electricity generation will reduce sulfur, nitrogen, mercury and particulate air pollution.
The researchers conducted a literature review on a wide range of issues related to unconventional energy, including well productivity, water requirements, well integrity, risks to surface and groundwater, seismic effects, air pollution and greenhouse gasses. In each section the scholars note questions in need of additional research and recommendations. The findings include:
Productivity and reserves
- Based on an analysis of the Barnett Shale in Texas, well production tends to drop sharply after initial fracking. Within five years, wells produce on average just 10% of what they did the first month of operation.
- Initial productivity (IP) rose in the Barnett Shale as companies learned as they went along. They also increased the intensity of extraction, lengthening horizontal drills by 75% and nearly doubling the amount of water used for a single “frack.”
- By 2011, productivity of new wells started to decrease as the “sweet spots” were exhausted and subsequent rigs produced less initially and over time. IP fell 22% between 2011 and 2012, despite an additional 10% increase in drilling length.
- Refracturing existing wells can increase the estimated ultimate recovery (EUR) by 30%.
- Because fracking is still evolving and estimation of reserves is based on well productivity that can change over time, reserve estimations should be regarded with caution. For example, in 2011 the Energy Information Agency (EIA) estimated that the U.S. had 827 trillion cubic feet of shale gas, but the following year dropped its estimate to 482 trillion cubic feet, a 40% decrease. (Note that some nongovermental organizations have calculated even lower forecasts.)
Water requirements and risks
- Fracking a single well can require anywhere from 2 to 20 million gallons of water, with another 25% used for operations such as drilling and extraction.
- While water use for fracking is in general small relative to agricultural and municipal consumption — it represents less than 1% of total water use in Texas, compared to 56% for crops and 26% for municipalities — it can be quite high in specific areas and time frames. For example, in counties located in the Haynesville, Eagle Ford, and Barnett shales, fracking operations were responsible for 11%, 38%, and 18% of total groundwater use. At its peak, net water use for fracking is projected to increase as much as 136% in the Haynesville Shale, 40% in Barnett and 89% in Eagle Ford.
- The volume of water used per energy generated — known as its water intensity — is lower for fracking than other fossil fuels and nuclear: Coal, nuclear and oil extraction use approximately two, three and ten times, respectively, as much water as fracking per energy unit, and corn ethanol can use 1,000 times more if the plants are irrigated. By comparison, renewables such as wind and photovoltaic solar energy require almost no water.
Well integrity and failure rates
- After the end of a well’s operational life, it is “plugged and abandoned” (P&A). In this process, “mechanical or cement barriers, such as packers, at different depths are used to prevent fluids from migrating up or down the well. Improperly abandoned wells provide a short circuit that connects the deeper layers to the surface.”
- Publicly available data on well failure rates are still relatively scarce. Pennsylvania State records from 2010 to 2013 indicated that that failure rates for Marcellus Shale wells were between 3% and 6%. The most extreme form of failure, a blowout, can cause tremendous damage but is rare: A 2013 study in GeoScienceWorld found that of 3,533 Marcellus wells drilled from 2008 to 2011, only four experienced blowouts.
- One standard measure of how closed wells are performing is “sustained casing pressure” (SCP), an indication that one or more barriers within a well has failed. While it does not always result in environmental contamination, SCP indicates that contamination is possible.
- Rates of sustained casing pressure vary widely: In a survey of 8,000 wells in the Gulf of Mexico approximately 12% showed evidence of SCP, with rates for individual fields varying between 2% and 29%. In Alberta, a survey of 316,000 wells found signs of SCP in 3.9% of them, with one region topping 15%. A 2014 study in Marine and Petroleum Geology found SCP rates “from 3% to 43% of wells in Bahrain, Canada, China, Indonesia, the United Kingdom, the United States, and offshore Norway and the Gulf of Mexico; 12 of 19 studies showed SCP values for ≥10% of wells.”
Risks to surface and groundwater
- While it is theoretically possible for fissures created by hydraulic fracturing to connect well bores with shallow aquifers, in practice this is unlikely: Targeted shale formations are generally 1 to 3 kilometers below the surface and the fissures created during operations rarely extend more than 600 meters. In general, contamination through existing fissures or abandoned wells is a “more plausible scenario,” as is poor well integrity. (Note that the EPA is investigating a contamination case in Wyoming where the sandstone formation being drilled was as close as 322 meters to the surface in an area with water wells that went as deep as 244 meters.)
- Two studies of the drinking water of a total of 209 homes overlaying the Marcellus Shale in Pennsylvania found evidence of hydrocarbon pollution. The first study found “17 times higher methane concentrations for the homes,” while the second concluded that “casing and cementing issues were the likeliest causes for the fugitive GM that they observed in the shallow aquifers.” On the other hand, a study of 127 homes over Arkansas’s Fayetteville Shale
found no evidence of contamination. - While the probability of groundwater contamination is “strongly debated and universally controversial,” drilling specialists have identified casing and cementing problems as one of their primary environmental concerns.
- Beyond the risk to groundwater supplies, U.S. oil and gas operations generate more than 2 billion gallons of wastewater daily: “These naturally occurring brines are often saline to hypersaline and contain potentially toxic levels of elements such as barium, arsenic, and radioactive radium.”
- More than 95% of the wastewater is injected deep underground; other disposal methods are “less common and far less preferable.” These include treating it at municipal waste facilities and spraying on public roads for purposes such as dust control. “An experimental application of [approximately] 300,000 liters of flowback water on 0.2 hectares of forest in West Virginia killed more than half the trees within two years.”
- Earthquakes induced by hydraulic fracturing are rare, and those that can be felt by human are rarer still — only “a handful” of cases have been documented so far, none of greater than 4 Mw. Some cases occur when fracturing is used in areas in existing fracture zones, which are sometimes intentionally targeted because they can result in increased gas production.
- Injection of groundwater can also induce seismic events, and the rate of such events has increased in tandem with unconventional energy extraction: “Between 1967 and 2000, geologists observed a steady background rate of 21 earthquakes of 3.0 Mw or greater in the central United States per year. Starting in 2001, when shale gas and other unconventional energy sources began to grow, the rate rose steadily to [approximately] 100 such earthquakes annually, with 188 in 2011 alone.”
- While earthquakes induced by wastewater injection are less frequent than those caused by fracking, their magnitude tends to be greater: “In 2011 alone, earthquakes of 4.0 to 5.3 Mw were linked to deep wastewater injection in locations such as Youngstown, Ohio; Guy, Arkansas; Snyder and Fashing, Texas; and Trinidad, Colorado.” The most severe, 5.7 Mw, destroyed 14 homes and injured two people in Oklahoma.
- Unconventional energy extraction is a source of air pollution throughout the preparation, extraction and closure phases. Access roads must be built, the well pad cleared and the bore itself drilled; diesel engines power the fracturing phase. During extraction, wastewater is stored in tanks or open ponds, and any volatile organic compounds (VOCs) are either vented or flared. According to a 2010 study from the U.S. Government Accountability Office (GAO), in 2006 up to 5% of the natural gas production on federal lands in the western United States was lost in this way.
- Atmospheric sampling has indicated even higher rates of escape: A 2013 study in Geophysical Research Letters estimated that in the Uinta Basin of eastern Utah, 55,000 kilograms of methane per hour leak into the atmosphere, the equivalent of 6.2% to 11.7% of total natural gas production in the region.
- Operations related to unconventional energy can also have substantial impacts on air quality: In the Denver basin, more than 6,000 petroleum and condensate tanks are responsible for more than 70% of total VOC emissions from all sources, according to the Colorado Department of Public Health and Environment.
- One of the greatest potential benefits of unconventional energy is the potential for natural gas to displace electrical generation from coal: “Replacing coal with natural gas for power generation would substantially reduce emissions of CO2, particulate matter (PM), nitrogen oxides (NOx), sulfur dioxide (SO2), and metals such as mercury (Hg).” However, as stated above, the study does not see worldwide coal consumption falling despite the rise in unconventional energy.
The researchers conclude with five recommendations. First, greater transparency is required from companies and regulating agencies. Some information is available on the FracFocus disclosure registry, but more is needed. Second, short- and long-term studies are required on the potential effects of fracking on operations on human health — “virtually no comprehensive studies have been published on this topic,” they note. Third, predrilling data, including environmental quality and human health, would be in all parties’ interests. Fourth, because most problems result from surface operations, including faulty wells, spills and leaks, additional work on best practices is required. Finally, funds should be created to address future, unknown problems that could arise from the current oil and gas boom. “Drilling millions of new oil and natural gas wells will inevitably lead to future issues,” they note, and authorities and firms should work to ensure that the resources are available to deal with them.
Related research: A 2014 study in Journal of Infrastructure Systems, “Estimating the Consumptive Use Costs of Shale Natural Gas Extraction on Pennsylvania Roadways,” analyzes the damage that fracking operations impose on local transportation infrastructure. The researchers, based at the RAND Corporation and Carnegie Mellon University, estimate that the road-reconstruction costs associated with a single horizontal well range from $5,000 to $10,000. While this figure appears small, because there were more than 1,700 wells drilled in Pennsylvania in 2011 alone, the total costs for that year was between $8.5 and $39 million — costs paid by state transportation authorities, and thus taxpayers.
- Journalists Resource
- Published on:
- October 31, 2014
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