Frack fluid

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Frac fluid (sometimes spelled as frack fluid), which is an abbreviation for fracturing fluid, is a combination of water, chemicals, and sand (or another type of proppant) that are injected into a crude oil or natural gas well to reduce friction pressure and create a fracture. During hydraulic fracturing (also known as fracking), fluid is injected at a high speed into a wellbore to enhance the release of oil or natural gas located under the Earth. The chemical composition of frac fluid can vary depending on the geological features near the area being fractured. On average, frac fluid contains between 98 percent and 99.5 percent water and sand. Between 0.5 percent and 2 percent of the fluid is composed of chemical additives, which are used to stop the growth of microorganisms, prevent well casing corrosion, increase the rate at which the fluid is injected, and reduce pressure, among other uses. The water is used in part to transport the chemicals and sand—the latter two of which are chosen to ease the production of oil or gas—from the wellhead to the bottom of the well to increase the well's production of oil and gas.[1][2]

Background

Frac fluid consists of water, sand (or other type of proppant), and chemical additives. The additives are used to increase the amount of oil or gas extracted from the well. The type and amount of chemical additives and proppants depend on the geology of the area around the well. For example, friction-reducing additives (also known as slickwater) may be added to reduce friction within a well.[2][3]

The fluid is injected into an oil or natural gas well to create fractures and expand the surface area of a reservoir so as to enhance oil and gas recovery. The proppants in the fluid (such as silica sand) are used to prevent the induced fracture from closing. These induced fractures create a pathway used by operators to recover oil or natural gas from the underground formation. In addition, frac fluid and water flows back out of the well. Operators either recycle this fluid for reuse in another oil or gas well or dispose of it at an injection facility. The portion of fluid that does not return to the surface remains either in the well or in rock formations thousands of feet under the Earth's surface.[2][4][5]

Regulation

The Energy Policy Act of 2005 modified federal law to exclude “the underground injection of fluids or propping agents (other than diesel fuels) pursuant to hydraulic fracturing operations related to oil, gas, or geothermal production activities” from the Environmental Protection Agency's (EPA) underground injection control program established by the Safe Drinking Water Act. The 2005 act effectively allows state governments to regulate fracking and frac fluid as they relate to underground drinking water sources, though state regulations must meet the minimum requirements outlined in applicable federal regulations.[6]

States can require companies that use hydraulic fracturing to meet state regulations on well casing, the use of injection wells, and the disclosure of chemical additives used in frac fluid. For example, a state may require oil and gas operators to disclose all chemical additives used in frac fluid publicly on the Internet. For example, the website FracFocus.org, a public chemical registry managed by the Groundwater Protection Council (a national group of state groundwater and injection well control agencies) and the Interstate Oil and Gas Compact Commission (a national group of state oil and gas regulators), is used by oil and gas companies to list the additives used in frac fluid. In addition, states may enact regulations allowing oil and gas companies to withhold certain chemicals that are considered a trade secret by the industry.[7][4][8]

Overview of fracking

Hydraulic fracturing, also known as fracking, is a method of oil and natural gas extraction. The process involves injecting fluid into subterranean rock formations at high pressure. The high-pressure fluid produces a fracture network that allows crude oil and natural gas inside dense rocks to flow into a wellbore and be extracted at the surface. The fluid (known as frac fluid) contains between 98 percent and 99.5 percent water and sand; between 0.5 percent and 2 percent of the fluid is composed of chemical additives, which are used to stop the growth of microorganisms, prevent well casing corrosion, increase the rate at which the fluid is injected, and reduce pressure, among other things.[9]

According to the U.S. Energy Information Administration (EIA), there were approximately 23,000 hydraulically fractured wells in the United States in 2000. In 2015, the United States contained approximately 300,000 hydraulically fractured wells, accounting for 67 percent of U.S. natural gas production and 51 percent of U.S. crude oil production.[10][11][12]

Water use in fracking

See also: Water pollution
The stages of the hydraulic fracturing water cycle
Click to enlarge.

2016 EPA study on fracking

See also: The EPA study on fracking and drinking water resources (2016)

On December 13, 2016, the Environmental Protection Agency (EPA) released a final report requested by Congress in 2010 on the impact of hydraulic fracturing (fracking) on drinking water resources. The EPA report stated that there was "scientific evidence that hydraulic fracturing activities can impact drinking water resources in the United States under some circumstances." An earlier draft version of the report, released in June 2015, concluded that fracking had not resulted in any widespread or systemic impact on drinking water quality. That conclusion was deleted in the report's final version. Instead, according to Tom Burke, EPA Deputy Administrator, "We [the EPA] found scientific evidence of impacts to drinking water resources at each stage of the hydraulic fracturing water cycle."[13] According to the report, the agency based its study on 1,200 scientific sources, peer review by the EPA's Science Advisory Board, and input from federal, state, local, tribal, and industry officials.[14][15] However, the EPA acknowledged that its findings were limited in scope, reporting that "uncertainties and data gaps limited the EPA's ability to fully assess impacts to drinking water resources both locally and nationally."

The December 2016 report is a finalized version of an interim report issued by the EPA in 2015. To read more about the interim report, see this article.

Findings

The EPA concluded that, in some circumstances, poorly constructed drilling wells and incorrect wastewater management affected drinking water resources, particularly near drilling sites. According to the report, effects on drinking water "ranged in severity, from temporary changes in water quality to contamination that made private drinking wells unusable." Instances where drinking water resources were more vulnerable included the following:

"
  • Water withdrawals for hydraulic fracturing in times or areas of low water availability, particularly in areas with limited or declining groundwater resources;
  • Spills during the management of hydraulic fracturing fluids and chemicals or produced water that result in large volumes or high concentrations of chemicals reaching groundwater resources;
  • Injection of hydraulic fracturing fluids into wells with inadequate mechanical integrity, allowing gases or liquids to move to groundwater resources;
  • Injection of hydraulic fracturing fluids directly into groundwater resources;
  • Discharge of inadequately treated hydraulic fracturing wastewater to surface water resources; and
  • Disposal or storage of hydraulic fracturing wastewater in unlined pits, resulting in contamination of groundwater resources.[16]
—Environmental Protection Agency[14]

The report focused on the potential impact on water sources during five stages of the fracking process:[14][15]

  • The acquisition of water to be used for fracking
  • The mixing of chemical additives and water to make fracking fluids
  • The injection of fracking fluids into a production well to create and enlarge fractures in the targeted production zone.
  • The collection of wastewater that returns through a well after the injection of fracking fluids
  • The management of wastewater through disposal or reuse.

Reactions

  • The American Petroleum Institute (API), which represents the oil and natural gas industry, criticized the EPA report as misleading. "It is beyond absurd for the administration to reverse course on its way out the door. The agency has walked away from nearly a thousand sources of information from published papers, technical reports, and peer-reviewed scientific reports demonstrating that industry practices, industry trends, and regulatory programs protect water resources at every step of the hydraulic fracturing process. Decisions like this amplify the public's frustrations with Washington," said API Upstream Director Erik Milito. Milito further stated, "Fortunately, the science and data clearly demonstrate that hydraulic fracturing does not lead to widespread, systemic impacts to drinking water resources. Unfortunately, consumers have witnessed five years and millions of dollars expended only to see a conclusion based in science changed to a conclusion based in political ambiguity."[17]
  • Energy in Depth, a website established by the Independent Petroleum Association of America, an oil and gas industry group, endorsed the EPA's conclusion, which it argues reinforces its view that there is no systematic impact from fracking, but also criticized the EPA's role in the report. A spokesperson for the website said, "EPA’s report blows apart the anti-fracking campaign’s most common claim, namely that hydraulic fracturing is polluting groundwater all across America" but that the "EPA did its best to inject politics into this good news by inflating concerns about groundwater, no doubt as a parting thank-you gift to the ‘Keep It In the Ground’ movement." The Keep It In the Ground movement refers to a collection of individuals, legislators, and organizations that oppose future oil and natural gas drilling.[13][18]
  • Food and Water Watch, an environmental group that opposes fracking, said the report confirmed its view that fracking contaminates drinking water. According to Wenonah Hauter, the group's executive director, "The EPA has confirmed what we’ve known all along: fracking can and does contaminate drinking water. We are pleased that the agency has acted on the recommendations of its Science Advisory Board and chosen [sic] be frank about the inherent harms and hazards of fracking. Today the Obama administration has rightly prioritized facts and science, and put public health and environmental protection over the profit-driven interests of the oil and gas industry."[19]
  • The Sierra Club, an environmental group that opposes fracking, said the report confirmed its view that fracking negatively affects drinking water. According to the group's official statement, "The Sierra Club applauds the EPA for its science-based fracking report, confirming what so many already knew; fracking presents a clear and present threat to our water, our public health, and our communities. For far too long, communities around the country have faced the daily threat of contaminated water, earthquakes, and an uncertain future due to fracking, all while oil and gas companies peddled the false claim that the process was safe. Today’s report ends this charade. No longer will families be told a lie as their health and safety are threatened."[20]

2015 Duke University study

A September 2015 study from researchers at Duke University found that fracking operations used 250 billion gallons of water from 2005 to 2014, which accounted for less than 1 percent of all water use nationwide. During that time, fracking also produced 210 billion gallons of wastewater. The study also found that "compared to other energy extraction methods, fracking is less water-intensive in the long run" because less water is used for each unit of energy that is produced. This study was funded by the National Science Foundation and the Duke University Energy Initiative.[21][22][23]

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See also

Footnotes

  1. ALL Consulting, Hydraulic Fracture Considerations for Natural Gas Wells of the Marcellus Shale,” accessed January 28, 2014
  2. 2.0 2.1 2.2 Geology.com, "Hydraulic Fracturing Fluids - Composition and Additives," accessed June 28, 2016
  3. Petrowiki, "Fracturing fluids and additives," accessed June 29, 2016
  4. 4.0 4.1 National Energy Technology Laboratory , "Modern Shale Gas Development in the United States: An Update" September 2013
  5. Southwestern Energy, "Frac Fluid - What's in it?" accessed March 9, 2017
  6. Congressional Research Service, "Hydraulic Fracturing and Safe Drinking Water Act Regulatory Issues," July 13, 2015
  7. Railroad Commission of Texas, "Hydraulic fracturing," accessed February 28, 2017
  8. Social Science Research Network, "Flowback: Federal Regulation of Wastewater from Hydraulic Fracturing," January 12, 2014
  9. Frack Wire, “What is Fracking,” accessed January 28, 2014
  10. University of Oklahoma, "Hydraulic Fracturing and Water Resources," accessed March 12, 2014
  11. U.S. Energy Information Administration, "Hydraulic fracturing accounts for about half of current U.S. crude oil production," March 15, 2016
  12. U.S. Energy Information Administration, "Hydraulically fractured wells provide two-thirds of U.S. natural gas production," May 5, 2016
  13. 13.0 13.1 The Hill, "EPA reverses course on fracking safety," December 13, 2016
  14. 14.0 14.1 14.2 U.S. Environmental Protection Agency, "Hydraulic Fracturing for Oil and Gas: Impacts from the Hydraulic Fracturing Water Cycle on Drinking Water Resources in the United States (Final Report)," accessed December 13, 2016
  15. 15.0 15.1 U.S. Environmental Protection Agency, "EPA Releases Final Report on Impacts from Hydraulic Fracturing Activities on Drinking Water," December 13, 2016
  16. Note: This text is quoted verbatim from the original source. Any inconsistencies are attributable to the original source.
  17. PR News Wire, "API: EPA distorts science in hydraulic fracturing study," December 13, 2016
  18. Energy in Depth, "*UPDATE* EPA Finalized Groundwater Report Reinforces No Widespread, Systemic Impacts from Fracking," December 13, 2016
  19. Common Dreams, " Statement of Wenonah Hauter, Executive Director, Food & Water Watch," December 13, 2016
  20. Sierra Club, "EPA report confirms threat posed by fracking," December 13, 2016
  21. American Chemical Society, "Water Footprint of Hydraulic Fracturing," September 15, 2015
  22. Duke University, "How Much Water Does U.S. Fracking Really Use?" September 15, 2015
  23. Reuters, "Water demand from fracking less than 1 percent of U.S. total: study," September 15, 2015
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