Environmental Risk Arising From Well-Construction Failure—Differences Between Barrier and Well Failure, and Estimates of Failure Frequency Across Common Well Types, Locations, and Well Age

King, George E.; King, Daniel E.

doi:10.2118/166142-pa

Cited by 83 publications

(41 citation statements)

References 56 publications

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“…The majority (89%) of horizontal wells also have production casings that are either fully cemented or cemented above the shallowest hydrocarbonbearing formation (20). This evidence supports the growing consensus that wellbore barrier failure, not the process of high-volume hydraulic fracturing itself, is the main thermogenic stray gas migration pathway (1,3,9,10,20,27,29,30).…”

Section: Resultssupporting

confidence: 62%

“…These rates are 1.6-4 times lower than the fraction of shale gas wells in Pennsylvania that have led to methane migration into groundwater (0.24%) (9). The contrast in rates highlights differences in geology, regulations, operators, and construction practices among different petroleum-producing basins (29)(30)(31). It should also be noted that the occurrence of thermogenic stray gas is likely underrepresented because of the spatial density of sampled water, willingness of landowners to have their water tested, and the possibility that stray hydrocarbons are rapidly oxidized under certain redox conditions (38).…”

Section: Resultsmentioning

confidence: 96%

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Groundwater methane in relation to oil and gas development and shallow coal seams in the Denver-Julesburg Basin of Colorado

Sherwood

Rogers

Lackey

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

104

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Unconventional oil and gas development has generated intense public concerns about potential impacts to groundwater quality. Specific pathways of contamination have been identified; however, overall rates of contamination remain ambiguous. We used an archive of geochemical data collected from 1988 to 2014 to determine the sources and occurrence of groundwater methane in the Denver-Julesburg Basin of northeastern Colorado. This 60,000-km2 region has a 60-y-long history of hydraulic fracturing, with horizontal drilling and high-volume hydraulic fracturing beginning in 2010. Of 924 sampled water wells in the basin, dissolved methane was detected in 593 wells at depths of 20–190 m. Based on carbon and hydrogen stable isotopes and gas molecular ratios, most of this methane was microbially generated, likely within shallow coal seams. A total of 42 water wells contained thermogenic stray gas originating from underlying oil and gas producing formations. Inadequate surface casing and leaks in production casing and wellhead seals in older, vertical oil and gas wells were identified as stray gas migration pathways. The rate of oil and gas wellbore failure was estimated as 0.06% of the 54,000 oil and gas wells in the basin (lower estimate) to 0.15% of the 20,700 wells in the area where stray gas contamination occurred (upper estimate) and has remained steady at about two cases per year since 2001. These results show that wellbore barrier failure, not high-volume hydraulic fracturing in horizontal wells, is the main cause of thermogenic stray gas migration in this oil- and gas-producing basin.

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Section: Resultssupporting

confidence: 62%

Section: Resultsmentioning

confidence: 96%

Groundwater methane in relation to oil and gas development and shallow coal seams in the Denver-Julesburg Basin of Colorado

Sherwood

Rogers

Lackey

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

104

View full text Add to dashboard Cite

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“…Well integrity to prevent leaks of gas and other fluids to groundwater or to ground surface is a cornerstone of environmental protection in all oil and gas drilling operations. Well integrity can be compromised as a result of poor completion or abandonment, formation damage around the wellbore, geomechanical effects, geochemical degradation of well cements, casing and tubing corrosion, and casing failure as a result of thermal or mechanical stresses (see King and King [2013] for a review). Poor well construction is a critical issue throughout the oil and gas industry and is not unique to any specific region, type of well, drilling period or sector of activity.…”

Section: Water Resources Researchmentioning

confidence: 99%

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Nowamooz

Lemieux

Molson

et al. 2015

Water Resources Research

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Methane and brine leakage rates and associated time scales along the cemented casing of a hypothetical decommissioned shale gas well have been assessed with a multiphase flow and multicomponent numerical model. The conceptual model used for the simulations assumes that the target shale formation is 200 m thick, overlain by a 750 m thick caprock, which is in turn overlain by a 50 m thick surficial sand aquifer, the 1000 m geological sequence being intersected by a fully penetrating borehole. This succession of geological units is representative of the region targeted for shale gas exploration in the St. Lawrence Lowlands (Qu ebec, Canada). The simulations aimed at assessing the impact of well casing cementation quality on methane and brine leakage at the base of a surficial aquifer. The leakage of fluids can subsequently lead to the contamination of groundwater resources and/or, in the case of methane migration to ground surface, to an increase in greenhouse gas emissions. The minimum reported surface casing vent flow (measured at ground level) for shale gas wells in Quebec (0.01 m 3 /d) is used as a reference to evaluate the impact of well casing cementation quality on methane and brine migration. The simulations suggest that an adequately cemented borehole (with a casing annulus permeability k c 1 mD) can prevent methane and brine leakage over a time scale of up to 100 years. However, a poorly cemented borehole (k c ! 10 mD) could yield methane leakage rates at the base of an aquifer ranging from 0.04 m 3 /d to more than 100 m 3 /d, depending on the permeability of the target shale gas formation after abandonment and on the quantity of mobile gas in the formation. These values are compatible with surface casing vent flows reported for shale gas wells in the St. Lawrence Lowlands (Quebec, Canada). The simulated travel time of methane from the target shale formation to the surficial aquifer is between a few months and 30 years, depending on cementation quality and hydrodynamic properties of the casing annulus. Simulated longterm brine leakage rates after 100 years for poorly cemented boreholes are on the order of 10 25 m 3 /d (10 mL/d) to 10 23 m 3 /d (1 L/d). Based on scoping calculations with a well-mixed aquifer model, these rates are unlikely to have a major impact on groundwater quality in a confined aquifer since they would only increase the chloride concentration in a pristine aquifer to 1 mg/L, which is significantly below the commonly recommended aesthetic objective of 250 mg/L for chloride.

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“…Oil and gas wells are constructed with multiple engineered barriers against fluid flow leakage into other aquifers, protected groundwater, and/or atmosphere [19]. Local loss of well integrity may occur when there is debonding of cement from casing or from the rock wall, when the well cement has wormholes or fractures, when the well cement is not properly set in the well annulus, or when the casing fails due to stress [10].…”

Section: Introductionmentioning

confidence: 99%

“…In all these cases, leakage of reservoir or formation fluids, inside or outside well casing, will be stopped by the next barrier (e.g., the next cement plug or the next well section with good quality cement). However, if a continuous leakage pathway is formed, then the well loses its integrity and fails as a whole [19]. In a study of more than 300,000 wells in Alberta, Bachu & Watson [20], have found that approximately 6.5% of the oil and gas wells in the province have lost their integrity, leading to surface casing vent flow or gas migration.…”

Section: Introductionmentioning

confidence: 99%

Arsenic and Selenium in Formation Waters: Environmental Implications for Carbon Dioxide Storage in Geological Media

Hitchon¹,

Bachu²

2017

WIT Transactions on Ecology and the Environment

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In an attempt to mitigate climate warming, CO2 is being stored in geological media, including deep strata in sedimentary basins where formation waters commonly have high salinity. While there are numerous studies of reactions between injected CO2 and formation waters, little attention has been given to problems which might arise in areas affected by the pressure build-up generated by CO2 injection, which may extend for tens to hundreds of kilometres from the injection site. This paper draws on information from the Alberta Basin (Canada), and considers possible contamination consequences should formation water leak into shallow protected groundwater, with particular reference to As and Se. Arsenic and selenium were determined in 300 formation waters from strata 800 m or deeper: i.e., at depths and locations potentially suitable for CO2 storage. Although in about 72% of samples both elements were below detection (0.1 mg L ) and Se (44 mg L -1 ) are far above those reported in other sedimentary basins. Most samples were from drill stem tests, so contamination by As-bearing chemicals was unlikely. The most likely source for both elements is pyrite present in the aquifer, with chloride being the main removal control. More than 20,000 oil and gas wells in Alberta have lost their integrity, resulting in gas migration and surface casing vent-flow, which, if within the area of pressure build-up, could be conduits for contaminating local groundwater. Dilution up to several thousand times would be required to render these waters safe in the groundwater regime -possible, though with a low probability. These results suggest the need for more attention to the effect of pressure build-up and formation water composition in CO2 storage projects.

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Environmental Risk Arising From Well-Construction Failure—Differences Between Barrier and Well Failure, and Estimates of Failure Frequency Across Common Well Types, Locations, and Well Age

Cited by 83 publications

References 56 publications

Groundwater methane in relation to oil and gas development and shallow coal seams in the Denver-Julesburg Basin of Colorado

Groundwater methane in relation to oil and gas development and shallow coal seams in the Denver-Julesburg Basin of Colorado

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Arsenic and Selenium in Formation Waters: Environmental Implications for Carbon Dioxide Storage in Geological Media

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