Environmental impact of fracking: Difference between revisions
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== Air emissions == |
== Air emissions == |
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The main hydraulic-fracturing-related air emissions are [[methane]] emissions from the wells during fracturing and emissions from hydraulic fracturing equipment, such as compressor stations. Whether natural gas produced by hydraulic fracturing causes higher well-to-burner emissions than gas produced from conventional wells is a matter of contention. Some studies have found that hydraulic fracturing has higher emissions due to gas released during completing wells as some gas returns to the surface, together with the fracturing fluids. Depending on their treatment, the well-to-burner emissions are 3.5%–12% higher than for conventional gas.<ref name="WEO2011full" /> A debate has arisen particularly around a study by professor Robert W. Howarth finding shale gas significantly worse for global warming than oil or coal.<ref name="howarth" /> Other researchers have criticized Howarth's analysis,<ref name=Cathles /><ref name=ipsnewsShale /> including Cathles ''et al.,'' whose estimates were substantially lower."<ref name=Howarth3 /> The U.S. EPA has estimated the methane leakage rate to be about 2.4% – well below Howarth’s estimate. The American Gas Association, and industry trade group, calculated a 1.2% leakage rate <ref name="McCurdyDave"/> based on the EPA's latest greenhouse gas inventory. A 2012 industry funded report coauthored by researchers at the U.S. Department of Energy’s [[National Renewable Energy Laboratory]] found emissions from shale gas, when burned for electricity, were “very similar” to those from so-called “conventional well” natural gas, and less than half the emissions of coal.<ref name="LoganJeffrey" /> Another industry affiliated study estimated the amount of methane leakage from shale gas development and production could be as low as less than 1% of total gas production, or as high as several percent.<ref name="Allen" /> In April 2013 the EPA lowered its estimate of how much methane gas is released to the atmosphere during the hydraulic fracturing process by 20%. Howarth objected, pointing out that other federal climate scientists from the [[National Oceanic and Atmospheric Administration]] (NOAA) have published recent studies documenting massive methane leaks from natural gas operations in Colorado and other Western states. He suggested that EPA needs an outside independent review of their process. The EPA said it is seeking more data, but stands by its new estimates. "<ref name="3news"/> An additional concern is that oil obtained through hydraulic fracturing contains chemicals used in hydraulic fracturing, which may increase the rate at which rail tank cars and pipelines corrode, potentially releasing their load and its gases.<ref name="Bloomberg08132013" /><ref name="reuters10112013" /> |
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The main hydraulic-fracturing-related air emissions are [[methane]] emissions from the wells during fracturing and emissions from hydraulic fracturing equipment, such as compressor stations. According to the study conducted by professor Robert W. Howarth et al. of [[Cornell University]], "3.6% to 7.9% of the methane from shale-gas production escapes to the atmosphere in venting and leaks over the lifetime of a well." According to the study, this is at least 30% more, and perhaps even 100% more, than from conventional gas production. The study explains these higher emissions with hydraulic fracturing and drill out following the fracturing.<ref name="howarth"/> Methane gradually breaks down in the atmosphere, forming carbon [[dioxide]]. It means its greenhouse-gas footprint is worse than coal or oil for timescales of less than fifty years.<ref name="howarth"/><ref name="howarth2"/> However, several studies have argued that the paper was flawed and/or come to completely different conclusions, including assessments by experts at the US Department of Energy,<ref name=Skone/> by [[Carnegie Mellon University]]<ref name=Jiang/> and the University of Maryland,<ref name=Hultman/> as well as by the [[Natural Resources Defense Council]], which concluded that the Howarth ''et al''. paper's use of a 20-year time horizon for global warming potential of methane is "too short a period to be appropriate for policy analysis."<ref name=Lashof/> In January 2012, Howarth's colleagues at [[Cornell University]] responded with their assessment, arguing that the Howarth paper was "seriously flawed" because it "significantly overestimate[s] the fugitive emissions associated with unconventional gas extraction, undervalue[s] the contribution of 'green technologies' to reducing those emissions to a level approaching that of conventional gas, base[s] their comparison between gas and coal on heat rather than electricity generation (almost the sole use of coal), and assume[s] a time interval over which to compute the relative climate impact of gas compared to coal that does not capture the contrast between the long residence time of {{CO2}} and the short residence time of methane in the atmosphere."<ref name=Cathles/> The authors of that response conclude that "shale gas has a GHG footprint that is half and perhaps a third that of coal," based upon "more reasonable leakage rates and bases of comparison." Howarth et al. responded to this criticism: "We stand by our approach and findings. The latest EPA estimate for methane emissions from shale gas falls within the range of our estimates but not those of Cathles et al, which are substantially lower."<ref name=Howarth3/><ref name=ipsnewsShale/> |
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A 2012 report coauthored by researchers at the U.S. Department of Energy's [[National Renewable Energy Laboratory]] found emissions from shale gas, when burned for electricity, were "very similar" to those from conventional well natural gas, and less than half the emissions of coal.<ref name="LoganJeffrey">{{cite report |title=Natural Gas and the Transformation of the U.S. Energy Sector: Electricity |first=Jeffrey |last=Logan |publisher= Joint Institute for Strategic Energy Analysis | url=http://www.nrel.gov/docs/fy13osti/55538.pdf |
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| year = 2012 | format = PDF |accessdate=27 March 2013}}</ref> |
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Several studies which have estimated lifecycle methane leakage from shale gas development and production have found a wide range of leakage rates, from less than 1% of total production to nearly 8%.<ref name=Trembath>{{cite web |first1=Alex |last1=Trembath |first2=Max |last2=Luke |first3= Michael |last3= Shellenberger | first4=Ted |last4=Nordhaus |title=Coal Killer: How Natural Gas Fuels the Clean Energy Revolution |publisher=Breakthrough institute | page = 22 |date=June 2013 |url=http://thebreakthrough.org/images/main_image/Breakthrough_Institute_Coal_Killer.pdf | format = PDF |accessdate=2 October 2013}}</ref> Using data from the Environmental Protection Agency's most recent Greenhouse Gas Inventory<ref>{{cite web|url=http://www.epa.gov/climatechange/ghgemissions/usinventoryreport.html |title=U.S. Greenhouse Gas Inventory Report |publisher=United States Environmental Protection Agency |date= |accessdate=2013-10-02}}</ref> yields a methane leakage rate of about 1.4%, down from 2.3% from the EPA's previous Inventory.<ref>{{cite web|url=http://insights.wri.org/news/2013/05/5-reasons-why-its-still-important-reduce-fugitive-methane-emissions |title=5 Reasons Why It's Still Important To Reduce Fugitive Methane Emissions |publisher=World Resources Institute |date= |accessdate=2013-10-02}}</ref> |
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The most comprehensive study of methane leakage from shale gas to date, initiated by the Environmental Defense Fund (EDF) and released in the Proceedings of the National Academy of Sciences on September 16, 2013,<ref name="Allen">{{cite journal | url= http://www.pnas.org/content/early/2013/09/10/1304880110.full.pdf+html | title=Measurements of methane emissions at natural gas production sites in the United States|last1=Allen |first1=David T. |last2=Torres |first2=Vincent N. |last3=Thomas |first3=James |last4=Sullivan |first4=David W. |last5=Harrison |first5=Matthew |last6=Hendler |first6=Al |last7=Herndon |first7=Scott C. |last8=Kolb |first8=Charles E. |last9=Fraser |first9=Matthew P. |last10=Hill |first10=A. Daniel |last11=Lamb |first11=Brian K. |last12=Miskimins |first12=Jennifer |last13=Sawyer |first13=Robert F. |last14=Seinfeld |first14=John H. |journal = Proceedings of the National Academy of Sciences | doi = 10.1073/pnas.1304880110 |date=16 September 2013| accessdate = 2013-10-02 | format = PDF}}</ref> finds that fugitive emissions in key stages of the natural gas production process are significantly lower than estimates in the EPA’s national emissions inventory (which are already quite low). The study reports direct measurements from 190 onshore natural gas sites across the country and estimates a leakage rate of 0.42% for gas production. Although the EDF study did not cover all stages of natural gas supply chain, subsequent studies are planned to estimate leakage rates in others parts of the system. |
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In 2008, measured ambient concentrations near drilling sites in [[Sublette County, Wyoming]] were frequently above the National Ambient Air Quality Standards (NAAQS) of 75ppb and have been recorded as high as 125 ppb.<ref name=tribOzoneWyoming/> A 2011 study for the city of [[Fort Worth, Texas]], examining air quality around natural gas sites "did not reveal any significant health threats."<ref name=fortworthtexas/><ref name=starFortWorthNoThreats/> In [[DISH, Texas]], elevated levels of [[disulfide]]s, [[benzene]], [[xylene]]s and [[naphthalene]] have been detected in the air, emitted from the compressor stations.<ref name="DISH TX SciAm"/> People living near shale gas drilling sites often "complain of headaches, diarrhea, nosebleeds, dizziness, blackouts, muscle spasms, and other problems."<ref name="DISH TX EHP"/> Cause-and-effect relationships have not been established in all cases.<ref name="DISH TX EHP" /> In [[Garfield County, Colorado]], another area with a high concentration of drilling rigs, [[volatile organic compound]] emissions increased 30% between 2004 and 2006; during the same period there was a rash of health complaints from local residents. Epidemiological studies that might confirm or rule out any connection between these complaints and fracking are virtually non-existent.<ref name="HeatOnGas"/> In 2012, researchers from the [[Colorado School of Public Health]] showed that air pollution caused by fracking may contribute to "acute and chronic health problems" for those living near drilling sites.<ref name=atthefrontAirImpacts/> |
In 2008, measured ambient concentrations near drilling sites in [[Sublette County, Wyoming]] were frequently above the National Ambient Air Quality Standards (NAAQS) of 75ppb and have been recorded as high as 125 ppb.<ref name=tribOzoneWyoming/> A 2011 study for the city of [[Fort Worth, Texas]], examining air quality around natural gas sites "did not reveal any significant health threats."<ref name=fortworthtexas/><ref name=starFortWorthNoThreats/> In [[DISH, Texas]], elevated levels of [[disulfide]]s, [[benzene]], [[xylene]]s and [[naphthalene]] have been detected in the air, emitted from the compressor stations.<ref name="DISH TX SciAm"/> People living near shale gas drilling sites often "complain of headaches, diarrhea, nosebleeds, dizziness, blackouts, muscle spasms, and other problems."<ref name="DISH TX EHP"/> Cause-and-effect relationships have not been established in all cases.<ref name="DISH TX EHP" /> In [[Garfield County, Colorado]], another area with a high concentration of drilling rigs, [[volatile organic compound]] emissions increased 30% between 2004 and 2006; during the same period there was a rash of health complaints from local residents. Epidemiological studies that might confirm or rule out any connection between these complaints and fracking are virtually non-existent.<ref name="HeatOnGas"/> In 2012, researchers from the [[Colorado School of Public Health]] showed that air pollution caused by fracking may contribute to "acute and chronic health problems" for those living near drilling sites.<ref name=atthefrontAirImpacts/> |
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Also transportation of necessary water volume for hydraulic fracturing, if done by [[truck]]s, can cause high volumes of air emissions, especially particulate matter emissions.<ref name = "BMP" /> There are also reports of health problems around compressors stations<ref name="DISH TX SciAm" /> or drilling sites,<ref name="DISH TX EHP"/> although a causal relationship was not established for the limited number of wells studied<ref name="DISH TX EHP"/> and another Texas government analysis found no evidence of effects.<ref name="TexasDSHS" /> |
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In [[DISH, Texas]], elevated levels of [[disulphide]]s, [[benzene]], [[xylene]]s and [[naphthalene]] have been detected in the air.<ref name="DISH TX SciAm"/> According to an article in 'Environmental Health Perspectives,' people living near shale gas drilling sites often "complain of headaches, diarrhea, nosebleeds, dizziness, blackouts, muscle spasms, and other problems."<ref name="DISH TX EHP"/> Cause-and-effect relationships have not been established.<ref name="DISH TX EHP" /> |
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== Water consumption == |
== Water consumption == |
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Hydraulic fracturing uses between {{convert|1.2|and|3.5|e6USgal}} of water per well, with large projects using up to {{convert|5|e6USgal}}. Additional water is used when wells are refractured.<ref name="CRO 2009"/><ref name="Penn State Water" /> An average well requires {{convert |3|to|8|e6USgal|m3}} of water over its lifetime.<ref name="DOE primer"/><ref name = "Penn State Water" /><ref name="ALL-Marcellus"/><ref name="US Geological Survey" /> According to the [[Oxford Institute for Energy Studies]], greater volumes of fracturing fluids are required in Europe, where the shale depths average 1.5 times greater than in the U.S.<ref name="shale Europe" /> |
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The large volumes of water required have raised concerns about fracking in arid areas, such as Karoo in South Africa.<ref name="NYTUrbina30Dec2011"/> During periods of low stream flow it may affect [[Water supply network|water supplies]] for municipalities and industries such as [[power generation]], as well as recreation and [[aquatic life]]. It may also require water overland piping from distant sources.<ref name="ALL-Marcellus"/> Over its lifetime an average well requires {{convert|3|to|5|e6USgal|m3}} of water for the initial hydraulic fracturing operation and possible restimulation frac jobs.<ref name="ALL-Marcellus"/><ref name="DOE primer"/> Using the case of the Marcellus Shale as an example, fracking accounted for {{convert|650|e6USgal/a|m3/a}} or less than 0.8% of annual water use in the area overlying the Marcellus Shale as of 2010.<ref name="ALL-Marcellus"/> To minimize water consumption, recycling is one possible option.<ref name="WEO2011full"/> |
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Concern has been raised over the increasing quantities of water for hydraulic fracturing. Use of water for hydraulic fracturing can divert water from stream flow, [[Water supply network|water supplies]] for municipalities and industries such as [[power generation]], as well as recreation and [[aquatic life]].<ref name=Grist81513>{{cite news|title=Fracking company wants to build new pipeline — for water|url=http://grist.org/news/fracking-company-wants-to-build-new-pipeline-for-water/|accessdate=August 16, 2013|newspaper=Grist|date=August 15, 2013|author=John Upton}}</ref> The large volumes of water required for most common hydraulic fracturing methods have raised concerns for arid regions, such as Karoo in South Africa,<ref name="NYTUrbina30Dec2011"/> and in Pennsylvania,<ref name="Jefferson letter 2008" /><ref name="Snow Shoe letter 2007" /> and in drought-prone Texas, and Colorado in North America.<ref name="water battles" /> It may also require water overland piping from distant sources.<ref name = "ALL-Marcellus" /> |
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==Groundwater contamination== |
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The 2011 University of Texas study described the environmental impact of each of the separate parts of the overall hydraulic fracturing process, or "phases of the shale gas development life cycle."<ref name="UT Study"/> These parts include of (1) drill pad construction and operation, (2) the construction, integrity, and performance of the wellbores, (3) the injection of the fluid once it is underground (which proponents consider the actual "fracking"), (4) the flowback of the fluid back towards the surface, (5) blowouts, often unreported, which spew hydraulic fracturing fluid and other byproducts across surrounding area, (5) integrity of other pipelines involved and (6) the disposal of the flowback, including waste water and other waste products.<ref name="fuelfix"/><ref name="vancouversun"/> Associated problems include (1) Groundwater Contamination, (2) Blowouts and House Explosions, (3) Water Consumption and Supply, (4) Spill Management and Surface Water Protection, (5) Atmospheric Emissions, (6) Health Effects<ref name="UT Study" /> All but the injection stage were reported to be sources of contamination in the University of Texas study.<ref name="UT Study"/> The study concluded that if hydraulic fracturing is to be conducted in an environmentally safe manner, these issues need to be addressed first.<ref name="UT Study" /> Proponents have reported that groundwater contamination doesn't come directly from the "fracking" part of the process (the injection of hydraulic fracturing chemicals into Shale rock formations) but from other parts of the hydraulic fracturing process. Injection cannot be accomplished, however, without the accompanying stages. Poorly constructed or damaged wellbores and pipelines can allow the fluid to flow into aquifers.<ref name="UT Study" /> Volatile chemicals held in waste water evaporation ponds can to evaporate into the atmosphere, or overflow. In one of the cases described by a 2012 Cornell University study (conducted in Colorado, Louisiana, New York, Ohio, Pennsylvania and Texas) impounded wastewater was released into a field and pond, killing at least 70 animals.<ref name="Cornellvet03092012" /> The runoff can also end up in groundwater systems. Groundwater may become contaminated by trucks carrying fracking chemicals and wastewater if they are involved in accidents on the way to fracking sites or disposal destinations. Disposal of fracking fluid by injection can cause earthquakes, and release of unprocessed or under-processed waste water into rivers can contaminate water supplies.<ref name="UT Study" /> Critics have noted that it is "difficult for researchers to be objective if their university receives a lot of grants and funds from the industry."<ref name="UT funding"/> An Energy Institute spokesperson said that the study was not funded by the industry. He said funds came from the university, which has a variety of funding sources.<ref name="UT funding" /> There are extensive links between UT and the oil & gas industry, with the giving of [[Royal Dutch Shell]] to the university currently standing at more than $24.8 million, $4m alone having been handed over for 2012.<ref name="UTweb 14Feb2012"/><ref name="HBJ 15Feb2012"/> Since 2011, Shell has partnered Texas in a program called [http://www.beg.utexas.edu/sutur/index.php Shell-UT Unconventional Research], and the university has a similar research program in place with [[Exxon Mobil]].<ref name="Clanton 13Sep2011"/> [[Halliburton]], the largest supplier of fracking services in the United States, has also given millions of dollars to the university.<ref name="UTweb 28Feb2007"/> |
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In [[DISH, Texas]], elevated levels of [[disulphide]]s, [[benzene]], [[xylene]]s and [[naphthalene]] have been detected in the air.<ref name="DISH TX SciAm"/> According to an article in 'Environmental Health Perspectives,' people living near shale gas drilling sites often "complain of headaches, diarrhea, nosebleeds, dizziness, blackouts, muscle spasms, and other problems."<ref name="DISH TX EHP"/> Cause-and-effect relationships have not been established.<ref name="DISH TX EHP" /> Additionally, the Colorado Oil & Gas Conservation Commission has found some wells containing thermogenic methane due to oil and gas development upon investigating complaints from residents.<ref name="AutoZV-32"/> |
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Some producers have developed hydraulic fracturing techniques that could reduce the need for water.<ref name="window.state.tx.us">[http://www.window.state.tx.us/specialrpt/water/gamechangers/fracturing.php Texas Water Report: Going Deeper for the Solution] Texas Comptroller of Public Accounts. Retrieved 2/11/14.</ref> Using carbon dioxide, liquid propane or other gases instead of water have been proposed to reduce water consumption.<ref>[http://www.technologyreview.com/news/512656/skipping-the-water-in-fracking/ "Skipping the Water in Fracking."]</ref> After it is used, the propane returns to its gaseous state and can be collected and reused. In addition to water savings, gas fracturing reportedly produces less damage to rock formations that can impede production.<ref name="window.state.tx.us"/> Recycled flowback water can be reused in hydraulic fracturing.<ref name="WEO2011full"/> It lowers the total amount of water used and reduces the need to dispose of wastewater after use. The technique is relatively expensive, however, since the water must be treated before each reuse and it can shorten the life of some types of equipment.<ref name="WSJ11202012" /> |
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A 2011 report by the Massachusetts Institute of Technology addressed groundwater contamination, noting "There has been concern that these fractures can also penetrate shallow freshwater zones and contaminate them with fracturing fluid, but there is no evidence that this is occurring. There is, however, evidence of natural gas migration into freshwater zones in some areas, most likely as a result of substandard well completion practices by a few operators. There are additional environmental challenges in the area of water management, particularly the effective disposal of fracture fluids". This study encourages the use of industry best practices to prevent such events from recurring.<ref name="AutoZV-33"/> |
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New data shows that water saved by using natural gas combined cycle plants instead of coal steam turbine plants saves 25–50 times more water than the amount of water needed to extract the gas using hydraulic fracturing.<ref>[http://iopscience.iop.org/1748-9326/8/4/045033/article?fromSearchPage=true Drought and the water–energy nexus in Texas] Environmental Research Letters. Retrieved 2/11/14.</ref> |
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A review published in February 2012 found no direct evidence that fracking's actual injection phase resulted in contamination of ground water, and suggests that reported problems occur due to leaks in its fluid or waste storage apparatus; the review says that methane in water wells in some areas probably comes from natural resources.<ref name =FrackMix1/><ref name=FrackMix2/> |
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==Groundwater contamination== |
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==Waste water management== |
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===Flowback=== |
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As the fracturing fluid flows back through the well, it consists of spent fluids and may contain dissolved constituents such as minerals and [[brine water]]s. It may account for about 30–70% of the original fracture fluid volume. In addition, natural [[formation water]]s may flow to the well and need treatment. approaches to managing these fluids, commonly known as [[produced water]], include [[underground injection]], municipal and commercial [[wastewater treatment]] and discharge, self‐contained systems at well sites or fields, or recycling to fracture future wells.<ref name=Arthur2/> However, the quantity of waste water needing treatment and the improper configuration of sewage plants have become an issue in some regions of the United States. Much of the wastewater from hydraulic fracturing operations is processed by public sewage treatment plants, which are not equipped to remove radioactive material and are not required to test for it.<ref name="Neshaminy 2009"/><ref name="Urbina 26Feb2011"/> |
As the fracturing fluid flows back through the well, it consists of spent fluids and may contain dissolved constituents such as minerals and [[brine water]]s. It may account for about 30–70% of the original fracture fluid volume. In addition, natural [[formation water]]s may flow to the well and need treatment. approaches to managing these fluids, commonly known as [[produced water]], include [[underground injection]], municipal and commercial [[wastewater treatment]] and discharge, self‐contained systems at well sites or fields, or recycling to fracture future wells.<ref name=Arthur2/> However, the quantity of waste water needing treatment and the improper configuration of sewage plants have become an issue in some regions of the United States. Much of the wastewater from hydraulic fracturing operations is processed by public sewage treatment plants, which are not equipped to remove radioactive material and are not required to test for it.<ref name="Neshaminy 2009"/><ref name="Urbina 26Feb2011"/> |
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Hydraulic fracturing can concentrate uranium, radium, radon and thorium in flowback.<ref name="Weinhold 2012" /> Estimates of the amount of injected fluid returning to the surface vary. Estimates of the fluid that returns to the surface with the gas range from 15-20%<ref name="Ohio DNR" /> to 30–70%. the fluid is often mixed with formation water.<ref name="netldoe" /><ref name=Arthur2/> Additional fluid may return to the surface through abandoned wells or other pathways.<ref name="DetrowS" /> After the flowback is recovered, [[formation water]], usually [[brine]], may continue to flow to the surface, requiring treatment or disposal. Approaches to managing these fluids, commonly known as flowback, [[produced water]], or wastewater, include [[Injection well#Waste disposal|underground injection]], [[sewage treatment|municipal waste water treatment plants]], [[industrial wastewater treatment]], self-contained systems at well sites or fields, and recycling to fracture future wells.<ref name="LoganJeffrey" /><ref name=Arthur2/><ref name="HopeyDon" /><ref name="LitvakAnya"/> One Duke University study reported that "Marcellus [Shale] wells produce significantly less wastewater per unit gas recovered (~35%) compared to conventional natural gas wells.”<ref name="Lutz 2013" /> In Colorado the volume of wastewater discharged to surface streams increased from 2008 to 2011.<ref name="LoganJeffrey" /> |
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==Health Risks Due to Environmental Contamination of Fracking Fluids== |
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Fracking fluids have the potential to enter water sources, and air currents through chemical spills, through evaporation of wastewater, and through errors in the drilling process.<ref name="Urbina 26Feb2011"/> Trace amounts of these chemicals may affect the health of those working on or living near the wells. In Colorado, the U.S. Agency for Toxic Substances and Disease Registry sampled 14 sites, and found high levels of carcinogens such as benzene, tetrachloroethene, and 1-4 dichlorobenzene.<ref name=ScienceLagsPropublica/> In July 2011, the EPA released new emissions guidelinees stating that current standards could lead to an unacceptably high risk of cancers for those living near drilling operations.<ref name=ScienceLagsPropublica/> Pediatric Environmental Health Specialty Units(PEHSU) also found chemical contamination of drinking water near fracking operations in New York and Pennsylvania that involved detectable and harmful levels of benzene toluene, ethyl benzene, xylene, ethylene glycol, glutaldehyde, and other biocides such as hydrochloric acid, and hydrogen treated light petroleum distillates.<ref name=PEHSUConcerningEffects /> Human exposure to these chemicals can result in cancer, adverse effects of the reproductive, neurological, and endocrine systems.<ref name=PEHSUConcerningEffects /> Exposure to specialized chemical solutions patented by energy service companies, such as Zetaflow, used by Weatherford International, may result in kidney and liver damage, irritated lung tissue, decreased blood pressure, dizziness, and vomiting according to their Meterial Safety Data Sheet.<ref name=AToxicSpew?/> |
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In 2013 the vacuum multi-effect membrane distillation system was introduced to treat flowback. It is a hybrid system that uses both distillation and [[reverse osmosis]] to process the water. The water is repeatedly distilled through a membrane onto a collector. The system is operated in a partial vacuum to reduce the water's boiling point to {{convert|50|-|80|C|F}}. The purified result is appropriate for use in irrigation and may be made potable according to the company offering the service. The residual is highly concentrated brine, which can be reinjected or recycled using other technology.<ref>{{cite web|author=Economist |url=http://www.economist.com/news/technology-quarterly/21590757-environmental-technology-combination-two-desalination-techniques-provides |title=Monitor: Clean that up |publisher=The Economist |date=2013-11-30 |accessdate=2013-12-15}}</ref> |
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PEHSU has linked higher vulnerability in children to health risks associated with chemical exposure to fracking fluids.<ref name=PEHSUConcerningEffects /> This increased risk is due to a higher ratio of consumption pound for pound versus adults' rate of consumption, along with the inability to metabolize certain toxants that the body is able to metabolize as an adult.<ref name=PEHSUConcerningEffects /> The same kind of vulnerability is also exhibited in development of the fetus during pregnancy, and health risks may involve neural tube defects, decreased birth perameters, and childhood leukemia.<ref name=PEHSUConcerningEffects /> |
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Surface spills are another concern surrounding the hydro-fracking process. In a 2013 at the American Industrial Hygiene Conference and Expo in Montreal, Quebec experts met to discuss this topic. It was found that 77% of surface spills that affected groundwater were recorded in Weld County, where 18,000 wells were active. Also on average about seven barrels of hydraulic fracturing liquid are spilled during each incident. Most spills occur because of equipment failure or engineering misjudgments.<ref>(Surface Spills, 2013</ref> The management practices behind hydraulic fracturing are crucial to the success of this process and also prove to be a large environmental concern.<ref>New Research of Surface Spills in Fracking Industry. (2013). Professional Safety, 58(9), 18.</ref><ref>name= savannahb022</ref> |
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The growing of oil and natural gas drilling employing fracking technology is steady around different regions of the United States, but the maintenance of wastewater gathered after the drilling process containing fracking fluids is lagging behind.<ref name=PennsylvaniaLackingResources /> In Pennsylvania, the Department of Environmental Protection reported that the resources to properly regulate wastewater-handling facilities were unavailable, inspecting facilities every 20 years rather than every 2 years as called for by regulation.<ref name=PennsylvaniaLackingResources /> |
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Volatile chemicals held in waste water evaporation ponds can to evaporate into the atmosphere, or overflow. In one of the cases described by a 2012 Cornell University study (conducted in Colorado, Louisiana, New York, Ohio, Pennsylvania and Texas) impounded wastewater was released into a field and pond, killing at least 70 animals.<ref name="Cornellvet03092012" /> The runoff can also end up in groundwater systems. Groundwater may become contaminated by trucks carrying fracking chemicals and wastewater if they are involved in accidents on the way to fracking sites or disposal destinations.<ref name="UT Study" /> |
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==Public health benefits of shale gas from hydraulic fracturing== |
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[[Richard A. Muller]], a Principal of the China Shale Fund,<ref>http://www.chinashalefund.com/ China Shale Fund </ref> argues that the benefits from [[shale gas]] made available by fracking, by displacing harmful air pollution from coal, far outweigh their combined environmental costs. In a 2013 report for the [[Centre for Policy Studies]], Muller writes that air pollution, mostly from coal burning, kills over three million people each year, primarily in the developing world. The report does not reference any studies on air pollution associated with gas produced through hydraulic fracturing.<ref>[http://www.cps.org.uk/files/reports/original/131202135150-WhyEverySeriousEnvironmentalistShouldFavourFracking.pdf Why Every Serious Environmentalist Should Favour Fracking], 2013 report by Richard A. Muller and Elizabeth A. Muller of [[Berkeley Earth]]</ref> |
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A 2011 report by the Massachusetts Institute of Technology addressed groundwater contamination, noting "there has been concern that these fractures can also penetrate shallow freshwater zones and contaminate them with fracturing fluid, but there is no evidence that this is occurring. There is, however, evidence of natural gas migration into freshwater zones in some areas, most likely as a result of substandard well completion practices by a few operators. There are additional environmental challenges in the area of water management, particularly the effective disposal of fracture fluids". This study encourages the use of industry best practices to prevent such events from recurring.<ref name="AutoZV-33"/> |
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==Radioactive contamination== |
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===Methane=== |
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Groundwater methane contamination is also a concern as it has adverse effect on water quality and in extreme cases may lead to potential explosion.<ref name="Urbina 26Feb2011" /><ref name="Duke study 2010"/> In 2006, over {{convert|7|e6cuft|m3}} of methane were released from a blown gas well in [[Clark, Wyoming]] and shallow groundwater was found to be contaminated.<ref name="AutoZV-23" /> A scientific study reported in the [[PNAS]] investigated concerns over fracking and well water. The study found high correlations of drilling activity and methane pollution of the drinking water.<ref>[http://www.philly.com/philly/news/special_packages/inquirer/marcellus-shale/Duke_Study_finds_Methane_gas_in_well_water_near_fracking_sites.html "Duke Study finds Methane gas in well water near fracking sites" May 9, 2011 Philly Inquirer]</ref> Methane contamination is not always caused by hydraulic fracturing. Drilling for ordinary drinking water wells can also cause methane release. Most recent studies make use of tests that can distinguish between the deep [[thermogenic]] methane released during gas/oil drilling, and the shallower [[biogenic]] methane that can be released during water-well drilling. While both forms of methane result from decomposition, thermogenic methane results from [[geothermal]] assistance deeper underground.<ref name=molofsky/><ref name="AutoZV-32"/> |
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According to the 2011 study of the [[MIT Energy Initiative]], "there is evidence of natural gas (methane) migration into freshwater zones in some areas, most likely as a result of substandard well completion practices i.e. poor quality cementing job or bad casing, by a few operators."<ref name="AutoZV-33"/> 2011 studies by the [[Colorado School of Public Health]] and [[Duke University]] also pointed to methane contamination stemming from hydraulic fracturing or its surrounding process.<ref name="Duke study 2010" /><ref name = "AutoZV-32" /> A study by Cabot Oil and Gas examined the Duke study using a larger sample size, found that methane concentrations were related to topography, with the highest readings found in low-lying areas, rather than related to distance from gas production areas. Using a more precise isotopic analysis, they showed that the methane found in the water wells came from both the Marcellus Shale (Middle Devonian) where hydraulic fracturing occurred, and from the shallower Upper Devonian formations.<ref name=molofsky /> A 2013 Duke study suggested that both defective cement seals in the upper part of wells and faulty steel linings within deeper layers may be allowing methane and injected fluid to seep into surface waters.<ref name="EhrenburgR" /> Abandoned gas and oil wells also provide conduits to the surface.<ref name="DetrowS" /> A recent Duke University study found methane concentrations six times higher and ethane concentrations were 23 times higher at residences within a kilometer of a shale gas well. Propane was also detected in 10 homes within a kilometer of drilling. The researchers reported that the methane, ethane and propane data, and new evidence from hydrocarbon and helium content, all suggested that drilling has affected the drinking water. They noted that the ethane and propane data were notable because there was no biological source of ethane and propane in the region and Marcellus gas is higher in both than are Upper Devonian gases.<ref name="PNAS06242013" /> |
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The Colorado Oil & Gas Conservation Commission has found some wells containing thermogenic methane due to oil and gas development upon investigating complaints from residents.<ref name="AutoZV-32"/> A review published in February 2012 found no direct evidence that fracking's actual injection phase resulted in contamination of ground water, and suggests that reported problems occur due to leaks in its fluid or waste storage apparatus; the review says that methane in water wells in some areas probably comes from natural resources.<ref name =FrackMix1/><ref name=FrackMix2/> |
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==Injected fluid== |
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{{See also|List of additives for hydraulic fracturing}} |
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{{Globalize/US|section |date=March 2014 |discuss=Talk:Hydraulic fracturing#US-centric }} |
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There are concerns about possible contamination by hydraulic fracturing fluid both as it is injected under high pressure into the ground and as it returns to the surface.<ref name = "NYT Waste Docs 26Feb2011" /><ref name="EhrenburgR" /> To mitigate the effect of hydraulic fracturing on groundwater, the well and ideally the shale formation itself should remain hydraulically isolated from other geological formations, especially freshwater aquifers.<ref name = "WEO2011full" /> |
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While some of the [[List of additives for hydraulic fracturing|chemicals used in hydraulic fracturing]] are common and generally harmless, some are known [[carcinogens]].<ref name="house1" /> Out of 2,500 hydraulic fracturing products, more than 650 contained known or possible human carcinogens regulated under the [[Safe Drinking Water Act]] or listed as hazardous air pollutants".<ref name = "house1" /> Between 2005 and 2009, 279 products had at least one component listed as "proprietary" or "trade secret" on their [[Occupational Safety and Health Administration]] (OSHA) required [[material safety data sheet]] (MSDS). The MSDS is a list of chemical components in the products of chemical manufacturers, and according to OSHA, a manufacturer may withhold information designated as "proprietary" from this sheet. Most companies participating in the investigation were unable to name the ingredients of the products they use, leading the committee to surmise these "companies are injecting fluids containing unknown chemicals about which they may have limited understanding of the potential risks posed to human health and the environment".<ref name="house1"/> Without knowing the identity of the proprietary components, regulators cannot test for their presence. This prevents government regulators from establishing baseline levels of the substances prior to hydraulic fracturing and documenting changes in these levels, thereby making it more difficult to prove that hydraulic fracturing is contaminating the environment with these substances.<ref name = "AutoZV-16" /> |
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Another 2011 study identified 632 chemicals used in natural gas operations. Only 353 of these are well-described in the scientific literature. The study indicated possible long-term health effects that might not appear immediately. The study recommended full disclosure of all products used, along with extensive air and water monitoring near natural gas operations; it also recommended that hydraulic fracturing's exemption from regulation under the US [[Safe Drinking Water Act]] be rescinded.<ref name = "AEHS 2011" /> Industry group ''Energy In Depth'', a research arm of the Independent Petroleum Association of America, contends that fracking "was never granted an 'exemption' from it... How can something earn an exemption from a law that never covered or even conceived of it in the first place?”<ref name="EnergyInDepth01" /> |
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Governments are responding to questions about the contents of hydraulic fracturing fluid by requiring disclosure via government agencies and public web site. The Irish regulatory regime requires full disclosure of all additives to Ireland's Environmental Protection Agency (Ireland). The European Union also requires such disclosure.<ref name="EU" /> In the US, the Ground Water Protection Council launched FracFocus.org, an online voluntary disclosure database for hydraulic fracturing fluids funded by oil and gas trade groups and the U.S. Department of Energy. The site has been met with some skepticism relating to proprietary information that is not included.<ref name = "HassBenjamin" /><ref name="SoraghanMike02" /> Some states have mandated fluid disclosure and incorporated FracFocus as the tool for disclosure.<ref name="WatsonMatt"/><ref name = "MaykuthAndrew" /> Also in the US, [[The FracTracker Alliance]] provides oil and gas-related data storage, analyses, and online and customized maps related to hydraulic fracturing on FracTracker.org.<ref name="PlainDealer04042013" /><ref name="FracTracker" /> |
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===Radioactivity=== |
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{{see also|Radionuclides associated with hydraulic fracturing}} |
{{see also|Radionuclides associated with hydraulic fracturing}} |
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There are concerns about the levels of radioactivity in wastewater from hydraulic fracturing and its potential impact on public health. Recycling this wastewater has been proposed as a partial solution, but this approach has limitations.<ref name="Urbina 01Mar2011" /> |
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''[[The New York Times]]'' has reported radiation in hydraulic fracturing wastewater released into rivers in [[Pennsylvania]].<ref name="Urbina 26Feb2011"/> It collected data from more than 200 natural gas wells in Pennsylvania and has posted a map entitled [http://www.nytimes.com/interactive/2011/02/27/us/natural-gas-map.html Toxic Contamination from Natural Gas Wells in Pennsylvania]. Sand containing gamma-emitting tracer isotopes is used to trace and measure fractures.<ref name="No5635712" /> The Water Research Foundation, Philadelphia Water Department, Water Environment Research Federation, and The American Water Works Association are currently investigating hydraulic fracturing as a potential source of the Iodine-131 found in Philadelphia's drinking water.<ref name="WRF report 2013">{{cite report |url=http://www.waterrf.org/ExecutiveSummaryLibrary/4486_ProjectSummary.pdf |title=Potential Impacts and Significance of Elevated 131 I on Drinking Water Sources [Project #4486] ORDER NUMBER: 4486|author=Timothy A. Bartrand and Jeffrey S. Rosen |date=October 2013 |publisher=Water Research Foundation|accessdate=11 November 2013}}</ref> Individuals exposed to high enough levels of radiation may experience symptoms of [[acute radiation syndrome]], including fatigue, [[leukopenia]], fever, diarrhea, vomiting, nose bleeds, dizziness, disorientation, low blood pressure, seizures, and tremors.<ref name="radiation effects"/> The ''Times'' stated "never-reported studies" by the [[United States Environmental Protection Agency]] and a "confidential study by the drilling industry" concluded that radioactivity in drilling waste cannot be fully diluted in rivers and other waterways.<ref name="NYT Waste Docs 26Feb2011"/> Despite this, as of early 2011 federal and state regulators did not require sewage treatment plants that accept drilling waste (which is mostly water) to test for radioactivity. In Pennsylvania, where the drilling boom began in 2008, most drinking-water intake plants downstream from those sewage treatment plants have not tested for radioactivity since before 2006.<ref name="Urbina 26Feb2011"/> ''The New York Times'' reporting has been criticized by aggrieved parties,<ref name="NYT letters 05Mar2011"/> but one venerable science writer has taken issue with one instance of the newspaper's presentation and explanation of its calculations regarding dilution,<ref name="Urbina 01Mar2011"/> charging that a lack of context made the article's analysis uninformative.<ref name="Petit 02Mar2011"/> |
''[[The New York Times]]'' has reported radiation in hydraulic fracturing wastewater released into rivers in [[Pennsylvania]].<ref name="Urbina 26Feb2011"/> It collected data from more than 200 natural gas wells in Pennsylvania and has posted a map entitled [http://www.nytimes.com/interactive/2011/02/27/us/natural-gas-map.html Toxic Contamination from Natural Gas Wells in Pennsylvania]. Sand containing gamma-emitting tracer isotopes is used to trace and measure fractures.<ref name="No5635712" /> The Water Research Foundation, Philadelphia Water Department, Water Environment Research Federation, and The American Water Works Association are currently investigating hydraulic fracturing as a potential source of the Iodine-131 found in Philadelphia's drinking water.<ref name="WRF report 2013">{{cite report |url=http://www.waterrf.org/ExecutiveSummaryLibrary/4486_ProjectSummary.pdf |title=Potential Impacts and Significance of Elevated 131 I on Drinking Water Sources [Project #4486] ORDER NUMBER: 4486|author=Timothy A. Bartrand and Jeffrey S. Rosen |date=October 2013 |publisher=Water Research Foundation|accessdate=11 November 2013}}</ref> Individuals exposed to high enough levels of radiation may experience symptoms of [[acute radiation syndrome]], including fatigue, [[leukopenia]], fever, diarrhea, vomiting, nose bleeds, dizziness, disorientation, low blood pressure, seizures, and tremors.<ref name="radiation effects"/> The ''Times'' stated "never-reported studies" by the [[United States Environmental Protection Agency]] and a "confidential study by the drilling industry" concluded that radioactivity in drilling waste cannot be fully diluted in rivers and other waterways.<ref name="NYT Waste Docs 26Feb2011"/> Despite this, as of early 2011 federal and state regulators did not require sewage treatment plants that accept drilling waste (which is mostly water) to test for radioactivity. In Pennsylvania, where the drilling boom began in 2008, most drinking-water intake plants downstream from those sewage treatment plants have not tested for radioactivity since before 2006.<ref name="Urbina 26Feb2011"/> ''The New York Times'' reporting has been criticized by aggrieved parties,<ref name="NYT letters 05Mar2011"/> but one venerable science writer has taken issue with one instance of the newspaper's presentation and explanation of its calculations regarding dilution,<ref name="Urbina 01Mar2011"/> charging that a lack of context made the article's analysis uninformative.<ref name="Petit 02Mar2011"/> |
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Several earthquakes in 2011, including a [[moment magnitude scale|4.0 magnitude]] quake on New Year's Eve that hit [[Youngstown, Ohio]], are likely linked to a disposal of hydraulic fracturing wastewater,<ref name="Kim" /> according to seismologists at [[Columbia University]].<ref name="AutoZV-37"/> A similar series of small earthquakes occurred in 2012 in Texas. Earthquakes are not common occurrences in either area. Disposal and injection wells are regulated under the [[Safe Drinking Water Act]] and UIC laws.<ref name="Underground Injection" /> |
Several earthquakes in 2011, including a [[moment magnitude scale|4.0 magnitude]] quake on New Year's Eve that hit [[Youngstown, Ohio]], are likely linked to a disposal of hydraulic fracturing wastewater,<ref name="Kim" /> according to seismologists at [[Columbia University]].<ref name="AutoZV-37"/> A similar series of small earthquakes occurred in 2012 in Texas. Earthquakes are not common occurrences in either area. Disposal and injection wells are regulated under the [[Safe Drinking Water Act]] and UIC laws.<ref name="Underground Injection" /> |
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==Health risks== |
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Hydraulic fracturing fluids have the potential to enter water sources, and air currents through chemical spills, through evaporation of wastewater, and through errors in the drilling process.<ref name="Urbina 26Feb2011"/> Trace amounts of these chemicals may affect the health of those working on or living near the wells. In Colorado, the U.S. Agency for Toxic Substances and Disease Registry sampled 14 sites, and found high levels of carcinogens such as benzene, tetrachloroethene, and 1-4 dichlorobenzene.<ref name=ScienceLagsPropublica/> In July 2011, the EPA released new emissions guidelinees stating that current standards could lead to an unacceptably high risk of cancers for those living near drilling operations.<ref name=ScienceLagsPropublica/> Pediatric Environmental Health Specialty Units(PEHSU) also found chemical contamination of drinking water near fracking operations in New York and Pennsylvania that involved detectable and harmful levels of benzene toluene, ethyl benzene, xylene, ethylene glycol, glutaldehyde, and other biocides such as hydrochloric acid, and hydrogen treated light petroleum distillates.<ref name=PEHSUConcerningEffects /> Human exposure to these chemicals can result in cancer, adverse effects of the reproductive, neurological, and endocrine systems.<ref name=PEHSUConcerningEffects /> Exposure to specialized chemical solutions patented by energy service companies, such as Zetaflow, used by Weatherford International, may result in kidney and liver damage, irritated lung tissue, decreased blood pressure, dizziness, and vomiting according to their Meterial Safety Data Sheet.<ref name=AToxicSpew?/> |
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PEHSU has linked higher vulnerability in children to health risks associated with chemical exposure to fracking fluids.<ref name=PEHSUConcerningEffects /> This increased risk is due to a higher ratio of consumption pound for pound versus adults' rate of consumption, along with the inability to metabolize certain toxants that the body is able to metabolize as an adult.<ref name=PEHSUConcerningEffects /> The same kind of vulnerability is also exhibited in development of the fetus during pregnancy, and health risks may involve neural tube defects, decreased birth perameters, and childhood leukemia.<ref name=PEHSUConcerningEffects /> |
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The growing of oil and natural gas drilling employing fracking technology is steady around different regions of the United States, but the maintenance of wastewater gathered after the drilling process containing fracking fluids is lagging behind.<ref name=PennsylvaniaLackingResources /> In Pennsylvania, the Department of Environmental Protection reported that the resources to properly regulate wastewater-handling facilities were unavailable, inspecting facilities every 20 years rather than every 2 years as called for by regulation.<ref name=PennsylvaniaLackingResources /> |
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[[Richard A. Muller]], a Principal of the China Shale Fund,<ref>http://www.chinashalefund.com/ China Shale Fund </ref> argues that the benefits from [[shale gas]] made available by fracking, by displacing harmful air pollution from coal, far outweigh their combined environmental costs. In a 2013 report for the [[Centre for Policy Studies]], Muller writes that air pollution, mostly from coal burning, kills over three million people each year, primarily in the developing world. The report does not reference any studies on air pollution associated with gas produced through hydraulic fracturing.<ref>[http://www.cps.org.uk/files/reports/original/131202135150-WhyEverySeriousEnvironmentalistShouldFavourFracking.pdf Why Every Serious Environmentalist Should Favour Fracking], 2013 report by Richard A. Muller and Elizabeth A. Muller of [[Berkeley Earth]]</ref> |
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==Anti-fracking movement== |
==Anti-fracking movement== |
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<ref name=AToxicSpew?>{{cite news | url= http://www.thedailybeast.com/newsweek/2008/08/19/a-toxic-spew.html | title=A Toxic Spew? |date=19 August 2008 |accessdate=6 May 2013}}</ref> |
<ref name=AToxicSpew?>{{cite news | url= http://www.thedailybeast.com/newsweek/2008/08/19/a-toxic-spew.html | title=A Toxic Spew? |date=19 August 2008 |accessdate=6 May 2013}}</ref> |
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<ref name="howarth2">{{cite journal |title=Should Fracking Stop? Extracting gas from shale increases the availability of this resource, but the health and environmental risks may be too high. ''Point: Yes, it's too high risk'' |last=Howarth |first=Robert W. |last2=Ingraffea |first2=Anthony |pages=271–275 |issue=477 |date=15 September 2011 |journal= [[Nature (journal)|Nature]] | doi=10.1038/477271a}}</ref> |
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<ref name=Skone>{{cite web |last=Skone |first=Timothy J. |title=Life Cycle Greenhouse Gas Analysis of Natural Gas Extraction & Delivery in the United States |publisher=[[National Energy Technology Laboratory]] |date=12 May 2011 |url=http://cce.cornell.edu/EnergyClimateChange/NaturalGasDev/Documents/PDFs/SKONE_NG_LC_GHG_Profile_Cornell_12MAY11_Final.pdf | format = PDF |accessdate=4 February 2012}}</ref> |
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<ref name=Jiang>{{cite journal |first1=Mohan |last1=Jiang |first2=W Michael |last2=Griffin |first3= Chris |last3= Hendrickson | first4=Paulina |last4=Jaramillo | first5= Jeanne |last5= VanBriesen | first6= Aranya | last6 = Venkatesh |year=2011 |title=Life cycle greenhouse gas emissions of Marcellus shale gas | url = http://iopscience.iop.org/1748-9326/6/3/034014/pdf/1748-9326_6_3_034014.pdf | format = PDF |journal=[[Environmental Research Letters]] | publisher = [[IOP Publishing]] |volume=6 |issue=3 |doi=10.1088/1748-9326/6/3/034014 |accessdate=4 February 2012}}</ref> |
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<ref name=PennsylvaniaLackingResources>{{cite news |url=http://www.propublica.org/article/wastewater-from-gas-drilling-boom-may-threaten-monongahela-river |publisher=Propublica |date=3 October 2009 |title=With Natural Gas Drilling Boom, Pennsylvania Faces an Onslaught of Wastewater |deadurl=no |accessdate=7 August 2013}}</ref> |
<ref name=PennsylvaniaLackingResources>{{cite news |url=http://www.propublica.org/article/wastewater-from-gas-drilling-boom-may-threaten-monongahela-river |publisher=Propublica |date=3 October 2009 |title=With Natural Gas Drilling Boom, Pennsylvania Faces an Onslaught of Wastewater |deadurl=no |accessdate=7 August 2013}}</ref> |
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<ref name=Hultman>{{cite journal |first1=Nathan |last1=Hultman |first2=Dylan |last2=Rebois |first3=Michael |last3=Scholten |first4=Christopher |last4=Ramig |year=2011 |title=The greenhouse impact of unconventional gas for electricity generation |url=http://iopscience.iop.org/1748-9326/6/4/044008/pdf/1748-9326_6_4_044008.pdf |format=PDF |journal=[[Environmental Research Letters]] |publisher=[[IOP Publishing]] |volume=6 |issue=4 |doi=10.1088/1748-9326/6/4/044008 |accessdate=4 February 2012}}</ref> |
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<ref name=Lashof>{{cite web |last=Lashof |first=Dan |title=Natural Gas Needs Tighter Production Practices to Reduce Global Warming Pollution |publisher=Natural Resources Defense Council |date=12 April 2011 |url=http://switchboard.nrdc.org/blogs/dlashof/natural_gas_needs_tighter_prod.html |accessdate=4 February 2012}}</ref> |
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<ref name=Cathles>{{cite journal |last1=Cathles |first1=Lawrence M. |last2=Brown |first2=Larry |last3=Taam |first3=Milton |last4=Hunter |first4=Andrew |year=2011 |journal=Climatic Change |doi=10.1007/s10584-011-0333-0 |url=http://link.springer.com/article/10.1007%2Fs10584-011-0333-0 |title=A commentary on "The greenhouse-gas footprint of natural gas in shale formations" |deadurl=no |accessdate=7 August 2013}}</ref> |
<ref name=Cathles>{{cite journal |last1=Cathles |first1=Lawrence M. |last2=Brown |first2=Larry |last3=Taam |first3=Milton |last4=Hunter |first4=Andrew |year=2011 |journal=Climatic Change |doi=10.1007/s10584-011-0333-0 |url=http://link.springer.com/article/10.1007%2Fs10584-011-0333-0 |title=A commentary on "The greenhouse-gas footprint of natural gas in shale formations" |deadurl=no |accessdate=7 August 2013}}</ref> |
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<ref name="Phil report 2010">{{cite report |url=http://www.phila.gov/water/pdfs/WQR2010-v201105.pdf |title=Annual Drinking Water Quality Report, 2010 |date=Spring 2011 |publisher=Philadelphia Water Department |accessdate=7 February 2012|format = PDF}}</ref> |
<ref name="Phil report 2010">{{cite report |url=http://www.phila.gov/water/pdfs/WQR2010-v201105.pdf |title=Annual Drinking Water Quality Report, 2010 |date=Spring 2011 |publisher=Philadelphia Water Department |accessdate=7 February 2012|format = PDF}}</ref> |
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<ref name="AAS 19Sep2011">{{cite news |url=http://www.statesman.com/business/norway-based-energy-company-ut-agree-on-5-1867592.html |title=Norway-based energy company, UT agree on $5 million research program |author=Barry Harrell |date=19 September 2011 |newspaper=The Austin American-Statesman |accessdate=5 March 2012}}</ref> |
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<ref name="Phillips 2011">{{cite web |url=http://stateimpact.npr.org/pennsylvania/2011/12/08/epa-blames-fracking-for-wyoming-groundwater-contamination/ |title=EPA Blames Fracking for Wyoming Groundwater Contamination |author=Susan Phillips |date=8 December 2011 |work=StateImpact Pennsylvania |publisher=WITF, WHYY & NPR |accessdate=6 February 2012}}</ref> |
<ref name="Phillips 2011">{{cite web |url=http://stateimpact.npr.org/pennsylvania/2011/12/08/epa-blames-fracking-for-wyoming-groundwater-contamination/ |title=EPA Blames Fracking for Wyoming Groundwater Contamination |author=Susan Phillips |date=8 December 2011 |work=StateImpact Pennsylvania |publisher=WITF, WHYY & NPR |accessdate=6 February 2012}}</ref> |
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<ref name="EPA Pavillion Dec2011">{{cite report|title=Investigation of Ground Water Contamination near Pavillion, Wyoming. Draft |first1=Dominic C. |last1=DiGiulio |first2= Richard T. |last2=Wilkin |first3= Carlyle |last3= Miller | first4=Gregory |last4 = Oberley |publisher = [[United States Environmental Protection Agency|EPA]] |url=http://www.epa.gov/region8/superfund/wy/pavillion/EPA_ReportOnPavillion_Dec-8-2011.pdf | month = December | year = 2011 | format = PDF |accessdate=23 March 2012}}</ref> |
<ref name="EPA Pavillion Dec2011">{{cite report|title=Investigation of Ground Water Contamination near Pavillion, Wyoming. Draft |first1=Dominic C. |last1=DiGiulio |first2= Richard T. |last2=Wilkin |first3= Carlyle |last3= Miller | first4=Gregory |last4 = Oberley |publisher = [[United States Environmental Protection Agency|EPA]] |url=http://www.epa.gov/region8/superfund/wy/pavillion/EPA_ReportOnPavillion_Dec-8-2011.pdf | month = December | year = 2011 | format = PDF |accessdate=23 March 2012}}</ref> |
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<ref name="UTweb 28Feb2007">{{cite web |url=http://www.utexas.edu/news/2007/02/28/support/ |title=Halliburton Gives $90,000 in Grants to The University of Texas at Austin |date=28 February 2007 |publisher=UT Austin website |accessdate=5 March 2012 |quote=Energy services company Halliburton has contributed $90,000 to support academic programs at The University of Texas at Austin, bringing the company's total university giving to nearly $7 million.}}</ref> |
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<ref name="UTweb 14Feb2012">{{cite web |url=http://www.utexas.edu/news/2012/02/14/shell_oil_invests/ |title=Shell Oil Company Invests Nearly $4 Million in The University of Texas at Austin |date=14 February 2012 |publisher=UT Austin website |accessdate=5 March 2012}}</ref> |
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<ref name="UT funding">{{cite news |url=http://www.lmoga.com/news/fracturing-has-no-direct-link-to-water-pollution-ut-study-finds/ |title=Fracturing ‘has no direct’ link to water pollution, UT study finds |date=17 February 2012 |newspaper=Fuel Fix |accessdate=20 March 2012}}</ref> |
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<ref name="HBJ 15Feb2012">{{cite news |url=http://www.bizjournals.com/houston/news/2012/02/15/shell-oil-invests-39m-in-ut.html |title=Shell Oil invests $3.9M in UT |author=Sandra Zaragoza |date=15 February 2012 |newspaper=Houston Business Journal |accessdate=5 March 2012}}</ref> |
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<ref name="Clanton 13Sep2011">{{cite news |url=http://www.chron.com/business/energy/article/Shell-UT-to-study-better-shale-production-methods-2167340.php |title=Shell, UT to study better shale production methods |author=Brett Clanton |date=13 September 2011 |newspaper=Houston Chronicle |accessdate=5 March 2011}}</ref> |
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<ref name="Statoil buys">{{cite news |url=http://dealbook.nytimes.com/2011/10/17/norways-statoil-to-acquire-brigham-exploration-for-4-4-billion/ |title=Norway’s Statoil to Acquire Brigham Exploration for $4.4 Billion |author=Scott, Mark |date=17 October 2011 |work=Dealb%k |publisher=New York Times |accessdate=4 March 2012}}</ref> |
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<ref name="radiation effects">{{cite web |url=http://www.mayoclinic.com/health/radiation-sickness/DS00432/DSECTION=symptoms |title=Radiation sickness |author=Mayo clinic staff |publisher=Mayo Clinic |accessdate=31 March 2012}}</ref> |
<ref name="radiation effects">{{cite web |url=http://www.mayoclinic.com/health/radiation-sickness/DS00432/DSECTION=symptoms |title=Radiation sickness |author=Mayo clinic staff |publisher=Mayo Clinic |accessdate=31 March 2012}}</ref> |
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<ref name="Underground Injection">{{cite web|title=EPA Underground Injection Control Program|url=http://water.epa.gov/type/groundwater/uic/index.cfm|accessdate=2012-04-13}}</ref> |
<ref name="Underground Injection">{{cite web|title=EPA Underground Injection Control Program|url=http://water.epa.gov/type/groundwater/uic/index.cfm|accessdate=2012-04-13}}</ref> |
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<ref name="McCurdyDave">{{cite web |title=The Importance of Accurate Data |url=http://www.truebluenaturalgas.org/importance-accurate-data | publisher= True Blue Natural Gas |accessdate=27 March 2013}}</ref> |
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<ref name="3news">{{cite news| url= http://www.3news.co.nz/Fracking-gas-leak-estimates-lowered/tabid/1160/articleID/295881/Default.aspx |work=3 News | place = NZ |title= Fracking gas leak estimates lowered| date=April 29, 2013}}</ref> |
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<ref name="Bloomberg08132013">{{cite news |url=http://www.bloomberg.com/news/2013-08-13/north-dakota-oil-boom-seen-adding-costs-for-rail-safety.html |title= North Dakota Oil Boom Seen Adding Costs for Rail Safety |author=Jim Efstathiou Jr. and Angela Greiling Keane |date=13 August 2013 |agency=[[Bloomberg]] |accessdate=19 January 2012}}</ref> |
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<ref name="reuters10112013" >{{cite news |url =http://www.reuters.com/article/2013/10/11/us-tesoro-spill-northdakota-idUSBRE9990VL20131011/|title=Corrosion may have led to North Dakota pipeline leak: regulator | first =Selam |last=Gebrekidan |date=11 October 2013 |publisher= [[Reuters]] |accessdate=31 December 2013}}</ref> |
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<ref name="TexasDSHS">{{cite web |title=DISH, TExas Exposure Investigation |url=http://www.dshs.state.tx.us/epitox/consults/dish_ei_2010.pdf | publisher= Texas DSHS |accessdate=27 March 2013}}</ref> |
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<ref name="CRO 2009">{{cite report |url= http://www.fas.org/sgp/crs/misc/R40894.pdf |title=Unconventional Gas Shales: Development, Technology, and Policy Issues |author= Andrews, Anthony et al. |date=30 October 2009 |publisher=Congressional Research Service |accessdate=22 February 2012|format = PDF | pages = 7; 23}}</ref> |
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<ref name="US Geological Survey">{{cite report |url=http://ar.water.usgs.gov/Fayetteville_Shale/abstracts.pdf |title=Modeling the Effects of Non-Riparian Surface Water Diversions on Flow Conditions in the Little Red Watershed |last=Cothren |first=Jackson |quote=...each well requires between 3 and 7 million gallons of water for hydraulic fracturing and the number of wells is expected to grow in the future |publisher=U. S. Geological Survey, Arkansas Water Science Center Arkansas Water Resources Center, American Water Resources Association, Arkansas State Section Fayetteville Shale Symposium 2012 |accessdate=16 September 2012 |format = PDF | page = 12}}</ref> |
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<ref name="shale Europe">{{cite web |last= Faucon |first= Benoît |date= 17 September 2012 | title= Shale-Gas Boom Hits Eastern Europe |url= http://online.wsj.com/article/SB10000872396390443866404577565244220252020.html | publisher= [[WSJ.com]] |accessdate= 17 September 2012}}</ref> |
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<ref name="water battles" >{{cite news |url = http://www.politico.com/story/2013/06/fracking-water-battle-92862.html|title=Fracking fuels water battles | author=Staff|date=16 June 2013 |work=Politico |agency= Associated Press | accessdate=26 June 2013}}</ref> |
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<ref name="WSJ11202012">{{cite news |first= Alison | last = Sider |first2=Ben |last2= Lefebvre |date= 20 November 2012|title = Drillers Begin Reusing 'Frack Water.' Energy Firms Explore Recycling Options for an Industry That Consumes Water on Pace With Chicago | url = http://online.wsj.com/news/articles/SB10001424052970203937004578077183112409260 | newspaper = The Wall Street Journal |accessdate= 20 October 2013 }}</ref> |
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<ref name="Weinhold 2012">{{cite web |last= Weinhold |first= Bob |date= 19 September 2012 |title= Unknown Quantity: Regulating Radionuclides in Tap Water |url= http://ehp.niehs.nih.gov/category/news/page/6/ |quote = Examples of human activities that may lead to radionuclide exposure include mining, milling, and processing of radioactive substances; wastewater releases from the hydraulic fracturing of oil and natural gas wells... Mining and hydraulic fracturing, or "fracking", can concentrate levels of uranium (as well as radium, radon, and thorium) in wastewater... | work= Environmental Health Perspectives | publisher = [[NIEHS]], [[NIH]] | accessdate = 11 February 2012 }}</ref> |
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<ref name="Ohio DNR" >{{cite report |url= http://www.ohiodnr.com/Portals/11/pdf/wastewater-fact-sheet.pdf|title=Waste water (Flowback)from Hydraulic Fracturing |author= Staff |date= |publisher=Ohio Department of Natural Resources |quote= Most of the water used in fracturing remains thousands of feet underground, however, about 15-20 percent returns to the surface through a steel-cased well bore and is temporarily stored in steel tanks or lined pits. The wastewater which returns to the surface after hydraulic fracturing is called flowback|accessdate=29 June 2013|format = PDF}}</ref> |
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<ref name="netldoe" >{{cite report |url= http://www.netl.doe.gov/technologies/oil-gas/Petroleum/projects/Environmental/Produced_Water/00975_MarcellusFlowback.html|title= Sustainable Management of Flowback Water during Hydraulic Fracturing of Marcellus Shale for Natural Gas Production |author= Sandy McSurdy & Radisav Vidic |date= 25 June 2013|publisher=National Energy Technology Laboratory, US Department of Energy |accessdate=29 June 2013|format = PDF}}</ref> |
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<ref name="DetrowS" >{{cite web |url= http://stateimpact.npr.org/pennsylvania/2012/10/09/perilous-pathways-how-drilling-near-an-abandoned-well-produced-a-methane-geyser/ |title=Perilous Pathways: How Drilling Near An Abandoned Well Produced a Methane Geyser| first =Scott | last = Detrow |date=9 October 2012 |work=StateImpact Pennsylvania |publisher= [[NPR]] |accessdate=29 June 2013}}</ref> |
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<ref name="AutoZV-23">[http://trib.com/news/state-and-regional/blowout-brings-scrutiny-to-energy-company/article_cea4bf57-e246-5acf-ac9d-8c5587ef7f83.html Blowout brings scrutiny to energy company]</ref> |
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<ref name="EnergyInDepth01">{{cite web |title=FAQ: Hydraulic Fracturing, SDWA, Fluids, and DeGette/Casey |url=http://www.energyindepth.org/wp-content/uploads/2009/03/faq_hf_sdwa_fluids_degettecasey.pdf | publisher=Energy In Depth | accessdate=27 March 2013}}</ref> |
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Revision as of 16:30, 23 March 2014
This article may require cleanup to meet Wikipedia's quality standards. The specific problem is: this is too US-centric and some of information presented in this article belongs better to the Environmental impact of hydraulic fracturing in the United States article. It also contains some original research which was discussed while cleaning-up the Hydraulic fracturing article. (August 2012) |
Environmental impact of hydraulic fracturing includes the potential contamination of ground water, risks to air quality, noise pollution, the potential migration of gases and hydraulic fracturing chemicals to the surface, the potential mishandling of waste, and the health effects of these, like cancer.[1][2] Many cases of suspected groundwater contamination have been documented.[3][4] The EPA has noted that "Ground water contamination with constituents such as those found at Pavillion is typically infeasible or too expensive to remediate or restore (GAO 1989)."[5] A review of a University of Texas Austin study led by Charles G. Groat, reported no direct evidence that fracking's actual injection phase resulted in contamination of ground water.[6][7][8] In the study "fracking" was defined as referring only to the injection of fluid under pressure and excluded the impact of equipment failure, spills, the nature of the fluids, preparations prior to injection, and events following the injection, such as disposal of wastewater.[6] The review suggests that problems occur due to leaks in its fluid or waste storage apparatus which it does not consider part of fracking. The review also says that gaps remain in understanding fracking.[7][8] Because hydraulic fracturing was invented in the United States,[9] and therefore has a longer history there, most of the studies of the environmental impact have been conducted there.
Scientific debate
It has been reported that the industry and governmental pressure have made it difficult to conduct and report the results of comprehensive studies of hydraulic fracturing. EPA investigations into the oil and gas industry's environmental impact have been narrowed in scope and/or reportedly had negative findings removed due to this pressure.[10][11][12] A 2012 Cornell University report noted that it was difficult to assess health impact because of legislation, proprietary secrecy, and non-disclosure agreements that allow hydraulic fracturing companies to keep the proprietary chemicals used in the fluid secret. Pre-drilling tests and other assessments have also found that water supplies—especially private water wells—often suffer from high levels of naturally occurring contaminants, as the US Geological Survey concluded in August 2011.[13] Nonetheless, these particular Cornell researchers recommended requiring disclosure of all hydraulic fracturing fluids, that nondisclosure agreements not be allowed when public health is at risk, testing animals (and their products) raised near hydraulic fracturing sites against animals raised near hydraulic fracturing sites prior to selling them to market, monitoring of water, soil, and air more closely, and testing the air, water, soil, and animals prior to drilling and at regular intervals thereafter. Despite the lack of conclusive data, however, the researchers also wrote that "a ban on shale gas drilling is essential for the protection of public health."[14] The co-chair of the Chemicals Technical Options Committee for the United Nations Environment Program, Dr. Ian Rae, recently criticized the Cornell researchers' conclusions, saying, "It certainly does not qualify as a scientific paper but is, rather, an advocacy piece that does not involve deep analysis of the data gathered to support its case." Rae added that the Cornell researchers "cannot be regarded as experts" in this particular field. Others have pointed out that the study does still raise important questions, and it echoes similar concerns of some landowners and environmental groups.[15] In addition, after court cases concerning contamination from hydraulic fracturing are settled, the documents are sealed. While the American Petroleum Institute denies that this practice has hidden problems with gas drilling, others believe it has and could lead to unnecessary risks to public safety and health.[16]
The New York Times reported that the results of the 2004 EPA study were censored due to strong industry influence and political pressure (regulatory capture).[10] An early draft of the study discussed the possibility of dangerous levels of fracking fluid contamination and mentioned "possible evidence" of aquifer contamination. The final report concluded simply that fracking "poses little or no threat to drinking water".[10] The study's scope was narrowed so that it only focused on the injection of fracking fluids, ignoring other aspects of the process such as disposal of fluids and environmental concerns such as water quality, fish kills, and acid burns. The study was concluded before public complaints of contamination started emerging.[17]: 780 The study's conclusion that the injection of fracking fluids into coalbed methane wells posed a minimal threat to underground drinking water sources[18] may have influenced the 2005 Congressional decision that hydraulic fracturing should continue to be regulated by the states and not under the federal Safe Drinking Water Act.
The 2012 EPA Hydraulic Fracturing Draft Plan was also narrowed. It does not include studying the effects of iodine-131 (found in Philadelphia's drinking water)[19][20][21] or other radioactive tracer isotopes used in hydraulic fracturing.[22][23][24] Nor does the draft plan include evaluating the impact of wastewater. Christopher Portier, director of the US CDC's National Center for Environmental Health and the Agency for Toxic Substances and Disease Registry, argued that, in addition to the EPA's plans to investigate the impact of fracking on drinking water, additional studies should be carried out to determine whether wastewater from the wells can harm people or animals and vegetables they eat.[25] A group of US doctors called for a moratorium on fracking in populated areas until such studies had been done.[26][27]
Proponents of hydraulic fracturing have claimed in the press and other media that the recent University of Texas Study ("Fact-Based Regulation for Environmental Protection in Shale Gas Development") found that hydraulic fracturing caused no environmental contamination,[28][29] although the study did note that other steps in the drilling process—excepting the actual injection of the fluid—have been sources of environmental contamination.[6] Conflicting interpretations of this study are based on disagreement between industry and the environmental community about what "hydraulic fracturing" actually is: Industry notes that hydraulic fracturing is a specific process, which takes place after the well has been drilled and the drilling equipment has left the pad; the environmental community, however, uses hydraulic fracturing, or "fracking," to describe the entire production phase. The radioactivity of the injected fluid itself was not assessed in the University of Texas study.[6]
As of 2009, state regulators from across the country stated that they had seen no evidence of hydraulic fracturing contaminating water in their respective jurisdictions.[30] In May 2011 EPA Administrator Lisa P. Jackson testified in a Senate Hearing Committee stating that she is not aware of any proof where the fracking process itself has contaminated water.[31] EPA and other reports released since that time, however, have identified hydraulic fracturing as the likely source of water contamination.[3][5][16][32][33][34]
Air emissions
The main hydraulic-fracturing-related air emissions are methane emissions from the wells during fracturing and emissions from hydraulic fracturing equipment, such as compressor stations. Whether natural gas produced by hydraulic fracturing causes higher well-to-burner emissions than gas produced from conventional wells is a matter of contention. Some studies have found that hydraulic fracturing has higher emissions due to gas released during completing wells as some gas returns to the surface, together with the fracturing fluids. Depending on their treatment, the well-to-burner emissions are 3.5%–12% higher than for conventional gas.[35] A debate has arisen particularly around a study by professor Robert W. Howarth finding shale gas significantly worse for global warming than oil or coal.[36] Other researchers have criticized Howarth's analysis,[37][38] including Cathles et al., whose estimates were substantially lower."[39] The U.S. EPA has estimated the methane leakage rate to be about 2.4% – well below Howarth’s estimate. The American Gas Association, and industry trade group, calculated a 1.2% leakage rate [40] based on the EPA's latest greenhouse gas inventory. A 2012 industry funded report coauthored by researchers at the U.S. Department of Energy’s National Renewable Energy Laboratory found emissions from shale gas, when burned for electricity, were “very similar” to those from so-called “conventional well” natural gas, and less than half the emissions of coal.[41] Another industry affiliated study estimated the amount of methane leakage from shale gas development and production could be as low as less than 1% of total gas production, or as high as several percent.[42] In April 2013 the EPA lowered its estimate of how much methane gas is released to the atmosphere during the hydraulic fracturing process by 20%. Howarth objected, pointing out that other federal climate scientists from the National Oceanic and Atmospheric Administration (NOAA) have published recent studies documenting massive methane leaks from natural gas operations in Colorado and other Western states. He suggested that EPA needs an outside independent review of their process. The EPA said it is seeking more data, but stands by its new estimates. "[43] An additional concern is that oil obtained through hydraulic fracturing contains chemicals used in hydraulic fracturing, which may increase the rate at which rail tank cars and pipelines corrode, potentially releasing their load and its gases.[44][45]
A 2012 report coauthored by researchers at the U.S. Department of Energy's National Renewable Energy Laboratory found emissions from shale gas, when burned for electricity, were "very similar" to those from conventional well natural gas, and less than half the emissions of coal.[41]
Several studies which have estimated lifecycle methane leakage from shale gas development and production have found a wide range of leakage rates, from less than 1% of total production to nearly 8%.[46] Using data from the Environmental Protection Agency's most recent Greenhouse Gas Inventory[47] yields a methane leakage rate of about 1.4%, down from 2.3% from the EPA's previous Inventory.[48]
The most comprehensive study of methane leakage from shale gas to date, initiated by the Environmental Defense Fund (EDF) and released in the Proceedings of the National Academy of Sciences on September 16, 2013,[42] finds that fugitive emissions in key stages of the natural gas production process are significantly lower than estimates in the EPA’s national emissions inventory (which are already quite low). The study reports direct measurements from 190 onshore natural gas sites across the country and estimates a leakage rate of 0.42% for gas production. Although the EDF study did not cover all stages of natural gas supply chain, subsequent studies are planned to estimate leakage rates in others parts of the system.
In 2008, measured ambient concentrations near drilling sites in Sublette County, Wyoming were frequently above the National Ambient Air Quality Standards (NAAQS) of 75ppb and have been recorded as high as 125 ppb.[49] A 2011 study for the city of Fort Worth, Texas, examining air quality around natural gas sites "did not reveal any significant health threats."[50][51] In DISH, Texas, elevated levels of disulfides, benzene, xylenes and naphthalene have been detected in the air, emitted from the compressor stations.[52] People living near shale gas drilling sites often "complain of headaches, diarrhea, nosebleeds, dizziness, blackouts, muscle spasms, and other problems."[53] Cause-and-effect relationships have not been established in all cases.[53] In Garfield County, Colorado, another area with a high concentration of drilling rigs, volatile organic compound emissions increased 30% between 2004 and 2006; during the same period there was a rash of health complaints from local residents. Epidemiological studies that might confirm or rule out any connection between these complaints and fracking are virtually non-existent.[2] In 2012, researchers from the Colorado School of Public Health showed that air pollution caused by fracking may contribute to "acute and chronic health problems" for those living near drilling sites.[54]
Also transportation of necessary water volume for hydraulic fracturing, if done by trucks, can cause high volumes of air emissions, especially particulate matter emissions.[55] There are also reports of health problems around compressors stations[52] or drilling sites,[53] although a causal relationship was not established for the limited number of wells studied[53] and another Texas government analysis found no evidence of effects.[56]
In DISH, Texas, elevated levels of disulphides, benzene, xylenes and naphthalene have been detected in the air.[52] According to an article in 'Environmental Health Perspectives,' people living near shale gas drilling sites often "complain of headaches, diarrhea, nosebleeds, dizziness, blackouts, muscle spasms, and other problems."[53] Cause-and-effect relationships have not been established.[53]
Water consumption
Hydraulic fracturing uses between 1.2 and 3.5 million US gallons (4.5 and 13.2 Ml) of water per well, with large projects using up to 5 million US gallons (19 Ml). Additional water is used when wells are refractured.[57][58] An average well requires 3 to 8 million US gallons (11,000 to 30,000 m3) of water over its lifetime.[59][58][60][61] According to the Oxford Institute for Energy Studies, greater volumes of fracturing fluids are required in Europe, where the shale depths average 1.5 times greater than in the U.S.[62]
Concern has been raised over the increasing quantities of water for hydraulic fracturing. Use of water for hydraulic fracturing can divert water from stream flow, water supplies for municipalities and industries such as power generation, as well as recreation and aquatic life.[63] The large volumes of water required for most common hydraulic fracturing methods have raised concerns for arid regions, such as Karoo in South Africa,[9] and in Pennsylvania,[64][65] and in drought-prone Texas, and Colorado in North America.[66] It may also require water overland piping from distant sources.[60]
Some producers have developed hydraulic fracturing techniques that could reduce the need for water.[67] Using carbon dioxide, liquid propane or other gases instead of water have been proposed to reduce water consumption.[68] After it is used, the propane returns to its gaseous state and can be collected and reused. In addition to water savings, gas fracturing reportedly produces less damage to rock formations that can impede production.[67] Recycled flowback water can be reused in hydraulic fracturing.[35] It lowers the total amount of water used and reduces the need to dispose of wastewater after use. The technique is relatively expensive, however, since the water must be treated before each reuse and it can shorten the life of some types of equipment.[69]
New data shows that water saved by using natural gas combined cycle plants instead of coal steam turbine plants saves 25–50 times more water than the amount of water needed to extract the gas using hydraulic fracturing.[70]
Groundwater contamination
Flowback
As the fracturing fluid flows back through the well, it consists of spent fluids and may contain dissolved constituents such as minerals and brine waters. It may account for about 30–70% of the original fracture fluid volume. In addition, natural formation waters may flow to the well and need treatment. approaches to managing these fluids, commonly known as produced water, include underground injection, municipal and commercial wastewater treatment and discharge, self‐contained systems at well sites or fields, or recycling to fracture future wells.[71] However, the quantity of waste water needing treatment and the improper configuration of sewage plants have become an issue in some regions of the United States. Much of the wastewater from hydraulic fracturing operations is processed by public sewage treatment plants, which are not equipped to remove radioactive material and are not required to test for it.[72][73]
Hydraulic fracturing can concentrate uranium, radium, radon and thorium in flowback.[74] Estimates of the amount of injected fluid returning to the surface vary. Estimates of the fluid that returns to the surface with the gas range from 15-20%[75] to 30–70%. the fluid is often mixed with formation water.[76][71] Additional fluid may return to the surface through abandoned wells or other pathways.[77] After the flowback is recovered, formation water, usually brine, may continue to flow to the surface, requiring treatment or disposal. Approaches to managing these fluids, commonly known as flowback, produced water, or wastewater, include underground injection, municipal waste water treatment plants, industrial wastewater treatment, self-contained systems at well sites or fields, and recycling to fracture future wells.[41][71][78][79] One Duke University study reported that "Marcellus [Shale] wells produce significantly less wastewater per unit gas recovered (~35%) compared to conventional natural gas wells.”[80] In Colorado the volume of wastewater discharged to surface streams increased from 2008 to 2011.[41]
In 2013 the vacuum multi-effect membrane distillation system was introduced to treat flowback. It is a hybrid system that uses both distillation and reverse osmosis to process the water. The water is repeatedly distilled through a membrane onto a collector. The system is operated in a partial vacuum to reduce the water's boiling point to 50–80 °C (122–176 °F). The purified result is appropriate for use in irrigation and may be made potable according to the company offering the service. The residual is highly concentrated brine, which can be reinjected or recycled using other technology.[81]
Surface spills are another concern surrounding the hydro-fracking process. In a 2013 at the American Industrial Hygiene Conference and Expo in Montreal, Quebec experts met to discuss this topic. It was found that 77% of surface spills that affected groundwater were recorded in Weld County, where 18,000 wells were active. Also on average about seven barrels of hydraulic fracturing liquid are spilled during each incident. Most spills occur because of equipment failure or engineering misjudgments.[82] The management practices behind hydraulic fracturing are crucial to the success of this process and also prove to be a large environmental concern.[83][84]
Volatile chemicals held in waste water evaporation ponds can to evaporate into the atmosphere, or overflow. In one of the cases described by a 2012 Cornell University study (conducted in Colorado, Louisiana, New York, Ohio, Pennsylvania and Texas) impounded wastewater was released into a field and pond, killing at least 70 animals.[14] The runoff can also end up in groundwater systems. Groundwater may become contaminated by trucks carrying fracking chemicals and wastewater if they are involved in accidents on the way to fracking sites or disposal destinations.[6]
A 2011 report by the Massachusetts Institute of Technology addressed groundwater contamination, noting "there has been concern that these fractures can also penetrate shallow freshwater zones and contaminate them with fracturing fluid, but there is no evidence that this is occurring. There is, however, evidence of natural gas migration into freshwater zones in some areas, most likely as a result of substandard well completion practices by a few operators. There are additional environmental challenges in the area of water management, particularly the effective disposal of fracture fluids". This study encourages the use of industry best practices to prevent such events from recurring.[85]
Methane
Groundwater methane contamination is also a concern as it has adverse effect on water quality and in extreme cases may lead to potential explosion.[73][86] In 2006, over 7 million cubic feet (200,000 m3) of methane were released from a blown gas well in Clark, Wyoming and shallow groundwater was found to be contaminated.[87] A scientific study reported in the PNAS investigated concerns over fracking and well water. The study found high correlations of drilling activity and methane pollution of the drinking water.[88] Methane contamination is not always caused by hydraulic fracturing. Drilling for ordinary drinking water wells can also cause methane release. Most recent studies make use of tests that can distinguish between the deep thermogenic methane released during gas/oil drilling, and the shallower biogenic methane that can be released during water-well drilling. While both forms of methane result from decomposition, thermogenic methane results from geothermal assistance deeper underground.[89][90]
According to the 2011 study of the MIT Energy Initiative, "there is evidence of natural gas (methane) migration into freshwater zones in some areas, most likely as a result of substandard well completion practices i.e. poor quality cementing job or bad casing, by a few operators."[85] 2011 studies by the Colorado School of Public Health and Duke University also pointed to methane contamination stemming from hydraulic fracturing or its surrounding process.[86][90] A study by Cabot Oil and Gas examined the Duke study using a larger sample size, found that methane concentrations were related to topography, with the highest readings found in low-lying areas, rather than related to distance from gas production areas. Using a more precise isotopic analysis, they showed that the methane found in the water wells came from both the Marcellus Shale (Middle Devonian) where hydraulic fracturing occurred, and from the shallower Upper Devonian formations.[89] A 2013 Duke study suggested that both defective cement seals in the upper part of wells and faulty steel linings within deeper layers may be allowing methane and injected fluid to seep into surface waters.[91] Abandoned gas and oil wells also provide conduits to the surface.[77] A recent Duke University study found methane concentrations six times higher and ethane concentrations were 23 times higher at residences within a kilometer of a shale gas well. Propane was also detected in 10 homes within a kilometer of drilling. The researchers reported that the methane, ethane and propane data, and new evidence from hydrocarbon and helium content, all suggested that drilling has affected the drinking water. They noted that the ethane and propane data were notable because there was no biological source of ethane and propane in the region and Marcellus gas is higher in both than are Upper Devonian gases.[92]
The Colorado Oil & Gas Conservation Commission has found some wells containing thermogenic methane due to oil and gas development upon investigating complaints from residents.[90] A review published in February 2012 found no direct evidence that fracking's actual injection phase resulted in contamination of ground water, and suggests that reported problems occur due to leaks in its fluid or waste storage apparatus; the review says that methane in water wells in some areas probably comes from natural resources.[7][8]
Injected fluid
Template:Globalize/US There are concerns about possible contamination by hydraulic fracturing fluid both as it is injected under high pressure into the ground and as it returns to the surface.[93][91] To mitigate the effect of hydraulic fracturing on groundwater, the well and ideally the shale formation itself should remain hydraulically isolated from other geological formations, especially freshwater aquifers.[35]
While some of the chemicals used in hydraulic fracturing are common and generally harmless, some are known carcinogens.[1] Out of 2,500 hydraulic fracturing products, more than 650 contained known or possible human carcinogens regulated under the Safe Drinking Water Act or listed as hazardous air pollutants".[1] Between 2005 and 2009, 279 products had at least one component listed as "proprietary" or "trade secret" on their Occupational Safety and Health Administration (OSHA) required material safety data sheet (MSDS). The MSDS is a list of chemical components in the products of chemical manufacturers, and according to OSHA, a manufacturer may withhold information designated as "proprietary" from this sheet. Most companies participating in the investigation were unable to name the ingredients of the products they use, leading the committee to surmise these "companies are injecting fluids containing unknown chemicals about which they may have limited understanding of the potential risks posed to human health and the environment".[1] Without knowing the identity of the proprietary components, regulators cannot test for their presence. This prevents government regulators from establishing baseline levels of the substances prior to hydraulic fracturing and documenting changes in these levels, thereby making it more difficult to prove that hydraulic fracturing is contaminating the environment with these substances.[94]
Another 2011 study identified 632 chemicals used in natural gas operations. Only 353 of these are well-described in the scientific literature. The study indicated possible long-term health effects that might not appear immediately. The study recommended full disclosure of all products used, along with extensive air and water monitoring near natural gas operations; it also recommended that hydraulic fracturing's exemption from regulation under the US Safe Drinking Water Act be rescinded.[95] Industry group Energy In Depth, a research arm of the Independent Petroleum Association of America, contends that fracking "was never granted an 'exemption' from it... How can something earn an exemption from a law that never covered or even conceived of it in the first place?”[96]
Governments are responding to questions about the contents of hydraulic fracturing fluid by requiring disclosure via government agencies and public web site. The Irish regulatory regime requires full disclosure of all additives to Ireland's Environmental Protection Agency (Ireland). The European Union also requires such disclosure.[97] In the US, the Ground Water Protection Council launched FracFocus.org, an online voluntary disclosure database for hydraulic fracturing fluids funded by oil and gas trade groups and the U.S. Department of Energy. The site has been met with some skepticism relating to proprietary information that is not included.[98][99] Some states have mandated fluid disclosure and incorporated FracFocus as the tool for disclosure.[100][101] Also in the US, The FracTracker Alliance provides oil and gas-related data storage, analyses, and online and customized maps related to hydraulic fracturing on FracTracker.org.[102][103]
Radioactivity
There are concerns about the levels of radioactivity in wastewater from hydraulic fracturing and its potential impact on public health. Recycling this wastewater has been proposed as a partial solution, but this approach has limitations.[104]
The New York Times has reported radiation in hydraulic fracturing wastewater released into rivers in Pennsylvania.[73] It collected data from more than 200 natural gas wells in Pennsylvania and has posted a map entitled Toxic Contamination from Natural Gas Wells in Pennsylvania. Sand containing gamma-emitting tracer isotopes is used to trace and measure fractures.[22] The Water Research Foundation, Philadelphia Water Department, Water Environment Research Federation, and The American Water Works Association are currently investigating hydraulic fracturing as a potential source of the Iodine-131 found in Philadelphia's drinking water.[105] Individuals exposed to high enough levels of radiation may experience symptoms of acute radiation syndrome, including fatigue, leukopenia, fever, diarrhea, vomiting, nose bleeds, dizziness, disorientation, low blood pressure, seizures, and tremors.[106] The Times stated "never-reported studies" by the United States Environmental Protection Agency and a "confidential study by the drilling industry" concluded that radioactivity in drilling waste cannot be fully diluted in rivers and other waterways.[93] Despite this, as of early 2011 federal and state regulators did not require sewage treatment plants that accept drilling waste (which is mostly water) to test for radioactivity. In Pennsylvania, where the drilling boom began in 2008, most drinking-water intake plants downstream from those sewage treatment plants have not tested for radioactivity since before 2006.[73] The New York Times reporting has been criticized by aggrieved parties,[107] but one venerable science writer has taken issue with one instance of the newspaper's presentation and explanation of its calculations regarding dilution,[104] charging that a lack of context made the article's analysis uninformative.[108]
According to a Times report in February 2011, wastewater at 116 of 179 deep gas wells in Pennsylvania "contained high levels of radiation," but its effect on public drinking water supplies is unknown because water suppliers are required to conduct tests of radiation "only sporadically".[109] The New York Post stated that the Pennsylvania Department of Environmental Protection reported that all samples it took from seven rivers in November and December 2010 "showed levels at or below the normal naturally occurring background levels of radioactivity", and "below the federal drinking water standard for Radium 226 and 228."[110] However the samples taken by the state at at least one river, (the Monongahela, a source of drinking water for parts of Pittsburgh), were taken upstream from the sewage treatment plants accepting drilling waste water.[111]
In Pennsylvania, much of this wastewater from hydraulic fracturing operations is processed by public sewage treatment plants. However, many sewage plants say that they are incapable of removing the radioactive components of this waste, which is often released into major rivers. Industry officials, though, claim that these levels are diluted enough that public health is not compromised.[73] This is a major concern as it provides the possibility for radioactive waste to enter into public water supplies.
The New York Times has implicated the DEP in industry-friendly inactivity, requesting rather than requiring them to handle their own flowback waste rather than sending it to public water treatment facilities.[112] However, former Pennsylvania DEP Secretary John Hanger, who served under Gov. Ed Rendell (D), has affirmed that municipal drinking water throughout the state is safe, but added that the environmentalists were accurate in stating that Pennsylvania's water treatment plants were not equipped to treat hydraulic fracturing water.[113] Current Pennsylvania DEP Secretary Michael Krancer serving under Gov. Tom Corbett (R) has denied that untreated wastewater is being discharged into the state's waterways.[114] It has been observed that Corbett received over a million dollars in gas industry contributions,[115] more than all his competitors combined, during his election campaign.[116] The New York Times reported that regulations are lax in Pennsylvania.[73] The oil and gas industry is generally left to police itself in the case of accidents. Unannounced inspections are not made by regulators: the companies report their own spills, and create their own remediation plans.[73] A recent review of the state-approved plans found them to appear to be in violation of the law.[73] Treatment plants are still not equipped to remove radioactive material and are not required to test for it.[73] Despite this, in 2009 the Ridgway Borough's public sewage treatment plant, in Elk County, PA, facility was sent wastewater containing radium and other types of radiation at at 275-780 times the drinking-water standard. The water being released from the plant was not tested for radiation levels.[73] Part of the problem is that growth in waste produced by the industry has outpaced regulators and state resources.[73] It should be noted that "safe drinking water standards" have not yet been set for many of the substances known to be in hydrofracturing fluids or their radioactivity levels,[73] and their levels are not included in public drinking water quality reports.[117]
Seismology
Hydraulic fracturing causes induced seismicity called microseismic events or microearthquakes. These microseismic events are often used to map the horizontal and vertical extent of the fracturing.[118] The magnitude of these events is usually too small to be detected at the surface, although the biggest micro-earthquakes may have the magnitude of about -1.6 (Mw). However, as of late 2012, there have been three instances of hydraulic fracturing, through induced seismicity, triggering quakes large enough to be felt by people: one each in the United States, Canada, and England.[119][120][121] The injection of waste water from gas operations, including from hydraulic fracturing, into saltwater disposal wells may cause bigger low-magnitude tremors, being registered up to 3.3 (Mw).[122]
A 2012 US Geological Survey study reported that a "remarkable" increase in the rate of M ≥ 3 earthquakes in the US midcontinent "is currently in progress", having started in 2001 and culminating in a 6-fold increase over 20th century levels in 2011. The overall increase was tied to earthquake increases in a few specific areas: the Raton Basin of southern Colorado (site of coalbed methane activity), and gas-producing areas in central and southern Oklahoma, and central Arkansas.[123] While analysis suggested that the increase is "almost certainly man-made", the USGS noted: "USGS's studies suggest that the actual hydraulic fracturing process is only very rarely the direct cause of felt earthquakes." The increased earthquakes were said to be most likely caused by increased injection of gas-well wastewater into disposal wells.[124] The injection of waste water from oil and gas operations, including from hydraulic fracturing, into saltwater disposal wells may cause bigger low-magnitude tremors, being registered up to 3.3 (Mw).[122]
Induced seismicity from hydraulic fracturing
The United States Geological Survey (USGS) has reported earthquakes induced by hydraulic fracturing and by disposal of hydraulic fracturing flowback into waste disposal wells in several locations. Bill Ellsworth, a geoscientist with the U.S. Geological Survey, has said, however: “We don’t see any connection between fracking and earthquakes of any concern to society.”[125] The National Research Council (part of the National Academy of Sciences) has also observed that hydraulic fracturing, when used in shale gas recovery, does not pose a serious risk of causing earthquakes that can be felt.[126] In 2013, Researchers from Columbia University and the University of Oklahoma demonstrated that in the midwestern United States, some areas with increased human-induced seismicity are susceptible to additional earthquakes triggered by the seismic waves from remote earthquakes. They recommended increased seismic monitoring near fluid injection sites to determine which areas are vulnerable to remote triggering and when injection activity should be ceased.[119][127]
A British Columbia Oil and Gas Commission investigation concluded that a series of 38 earthquakes (magnitudes ranging from 2.2 to 3.8 on the Richter scale) occurring in the Horn River Basin area between 2009 and 2011 were caused by fluid injection during hydraulic fracturing in proximity to pre-existing faults. The tremors were small enough that only one of them was reported felt by people; there were no reports of injury or property damage.[128]
A report in the UK concluded that hydraulic fracturing was the likely cause of two small tremors (magnitudes 2.3 and 1.4 on the Richter scale) that occurred during hydraulic fracturing of shale.[129][130][131]
Induced seismicity from water disposal wells
According to the USGS only a small fraction of roughly 40,000 waste fluid disposal wells for oil and gas operations in the United States have induced earthquakes that are large enough to be of concern to the public.[120] Although the magnitudes of these quakes has been small, the USGS says that there is no guarantee that larger quakes will not occur.[132] In addition, the frequency of the quakes has been increasing. In 2009, there were 50 earthquakes greater than magnitude 3.0 in the area spanning Alabama and Montana, and there were 87 quakes in 2010. In 2011 there were 134 earthquakes in the same area, a sixfold increase over 20th century levels.[133] There are also concerns that quakes may damage underground gas, oil, and water lines and wells that were not designed to withstand earthquakes.[132][134]
Several earthquakes in 2011, including a 4.0 magnitude quake on New Year's Eve that hit Youngstown, Ohio, are likely linked to a disposal of hydraulic fracturing wastewater,[119] according to seismologists at Columbia University.[135] A similar series of small earthquakes occurred in 2012 in Texas. Earthquakes are not common occurrences in either area. Disposal and injection wells are regulated under the Safe Drinking Water Act and UIC laws.[136]
Health risks
Hydraulic fracturing fluids have the potential to enter water sources, and air currents through chemical spills, through evaporation of wastewater, and through errors in the drilling process.[73] Trace amounts of these chemicals may affect the health of those working on or living near the wells. In Colorado, the U.S. Agency for Toxic Substances and Disease Registry sampled 14 sites, and found high levels of carcinogens such as benzene, tetrachloroethene, and 1-4 dichlorobenzene.[137] In July 2011, the EPA released new emissions guidelinees stating that current standards could lead to an unacceptably high risk of cancers for those living near drilling operations.[137] Pediatric Environmental Health Specialty Units(PEHSU) also found chemical contamination of drinking water near fracking operations in New York and Pennsylvania that involved detectable and harmful levels of benzene toluene, ethyl benzene, xylene, ethylene glycol, glutaldehyde, and other biocides such as hydrochloric acid, and hydrogen treated light petroleum distillates.[138] Human exposure to these chemicals can result in cancer, adverse effects of the reproductive, neurological, and endocrine systems.[138] Exposure to specialized chemical solutions patented by energy service companies, such as Zetaflow, used by Weatherford International, may result in kidney and liver damage, irritated lung tissue, decreased blood pressure, dizziness, and vomiting according to their Meterial Safety Data Sheet.[139]
PEHSU has linked higher vulnerability in children to health risks associated with chemical exposure to fracking fluids.[138] This increased risk is due to a higher ratio of consumption pound for pound versus adults' rate of consumption, along with the inability to metabolize certain toxants that the body is able to metabolize as an adult.[138] The same kind of vulnerability is also exhibited in development of the fetus during pregnancy, and health risks may involve neural tube defects, decreased birth perameters, and childhood leukemia.[138]
The growing of oil and natural gas drilling employing fracking technology is steady around different regions of the United States, but the maintenance of wastewater gathered after the drilling process containing fracking fluids is lagging behind.[140] In Pennsylvania, the Department of Environmental Protection reported that the resources to properly regulate wastewater-handling facilities were unavailable, inspecting facilities every 20 years rather than every 2 years as called for by regulation.[140]
Richard A. Muller, a Principal of the China Shale Fund,[141] argues that the benefits from shale gas made available by fracking, by displacing harmful air pollution from coal, far outweigh their combined environmental costs. In a 2013 report for the Centre for Policy Studies, Muller writes that air pollution, mostly from coal burning, kills over three million people each year, primarily in the developing world. The report does not reference any studies on air pollution associated with gas produced through hydraulic fracturing.[142]
Anti-fracking movement
An anti-fracking movement has emerged both internationally with involvement of international environmental organizations and nation states such as France and locally in affected areas such as Balcombe in Sussex where the Balcombe drilling protest was in progress during summer 2013.[143]
See also
- Cost of electricity by source
- Directional drilling
- Environmental concerns with electricity generation
- Environmental impact of petroleum
- Environmental impact of the oil shale industry
- Environmental impact of hydraulic fracturing in the United States
- ExxonMobil Electrofrac
- Gasland a 2011 documentary nominated for an Oscar
- FrackNation a 2012 documentary
- Hydraulic fracturing by country
- Hydraulic fracturing in the United States
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{{cite report}}
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{{cite report}}
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Covering much of the roughly 800 miles between Johannesburg and Cape Town, this arid expanse – its name [Karoo] means "thirsty land" – sees less rain in some parts than the Mojave Desert.
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{{cite journal}}
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ignored (|url-status=
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{{cite report}}
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Hydrofracturing a horizontal Marcellus well may use 4 to 8 million gallons of water, typically within about 1 week. However, based on experiences in other major U.S. shale gas fields, some Marcellus wells may need to be hydrofractured several times over their productive life (typically five to twenty years or more)
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{{cite report}}
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ignored (help) - ^ a b Arthur, J. Daniel; Uretsky, Mike; Wilson, Preston (May 5–6, 2010). Water Resources and Use for Hydraulic Fracturing in the Marcellus Shale Region (PDF). Meeting of the American Institute of Professional Geologists. Pittsburgh: ALL Consulting. p. 3. Retrieved 2012-05-09.
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...each well requires between 3 and 7 million gallons of water for hydraulic fracturing and the number of wells is expected to grow in the future
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Examples of human activities that may lead to radionuclide exposure include mining, milling, and processing of radioactive substances; wastewater releases from the hydraulic fracturing of oil and natural gas wells... Mining and hydraulic fracturing, or "fracking", can concentrate levels of uranium (as well as radium, radon, and thorium) in wastewater...
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Most of the water used in fracturing remains thousands of feet underground, however, about 15-20 percent returns to the surface through a steel-cased well bore and is temporarily stored in steel tanks or lined pits. The wastewater which returns to the surface after hydraulic fracturing is called flowback
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The process of hydraulic fracturing a well as presently implemented for shale gas recovery does not pose a high risk for inducing felt seismic events.
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requires|url=
(help)CS1 maint: date and year (link) - ^ Soraghan, Mike (29 March 2012). "'Remarkable' spate of man-made quakes linked to drilling, USGS team says". EnergyWire. E&E. Retrieved 2012-11-09.
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suggested) (help) - ^ http://www.chinashalefund.com/ China Shale Fund
- ^ Why Every Serious Environmentalist Should Favour Fracking, 2013 report by Richard A. Muller and Elizabeth A. Muller of Berkeley Earth
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