Unconventional oil and gas spills: Materials, volumes, and risks to surface waters in four states of the U.S.

Maloney, Kelly O.; Baruch‐Mordo, Sharon; Patterson, Lauren A.; Nicot, Jean‐Philippe; Entrekin, Sally A.; Fargione, Joseph; Kiesecker, Joseph M.; Konschnik, Katherine E.; Ryan, Joseph N.; Trainor, Anne M.; Saiers, James E.; Wiseman, Hannah Jacobs

doi:10.1016/j.scitotenv.2016.12.142

Cited by 95 publications

(60 citation statements)

References 33 publications

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“…Spilled fluids included pit fluids, fuels, mud, fracturing fluid, chemicals, flowback, and brine. Synthesizing spill data from shale and tight gas wells in four U.S. states from 2005 to 2014, Maloney et al (2017) showed that spill rates were increasing in Colorado, New Mexico, and North Dakota over time, while Pennsylvania spill rates peak and decrease over time as discussed above. In the Niobrara Shale formation in northeastern Colorado, for example, the spill rate remained relatively constant from 2007 to 2011 at 1 spill recorded for every 100 wells, while from 2012 to 2014 the rate of spills doubled to 1 in 50 (Armstrong et al 2017).…”

Section: Mechanism Methods Of Quantificationmentioning

confidence: 87%

“…In the Niobrara Shale formation in northeastern Colorado, for example, the spill rate remained relatively constant from 2007 to 2011 at 1 spill recorded for every 100 wells, while from 2012 to 2014 the rate of spills doubled to 1 in 50 (Armstrong et al 2017). Synthesizing spill data from shale and tight gas wells in four U.S. states from 2005 to 2014, Maloney et al (2017) showed that spill rates were increasing in Colorado, New Mexico, and North Dakota over time, while Pennsylvania spill rates peak and decrease over time as discussed above. Spill rates were between 2 and 16 per 100 new wells, up to 47% of which were located within each state's respective stream setback limits, suggesting possible surface water contamination.…”

Section: Methods Of Quantificationmentioning

confidence: 99%

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Towards Quantifying the Likelihood of Water Resource Impacts from Unconventional Gas Development

2018

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Gas production from unconventional reservoirs has led to widespread environmental concerns. Despite several excellent reviews of various potential impacts to water resources from unconventional gas production, no study has systematically and quantitatively assessed the potential for these impacts to occur. We use empirical evidence and numerical and analytical models to quantify the likelihood of surface water and groundwater contamination, and shallow aquifer depletion from unconventional gas developments. These likelihoods are not intended to be exact. They provide a starting point for comparing the probabilities of adverse impacts between types of water resources and pathways. This analysis provides much needed insight into what are "probable" rather than simply "possible" impacts. The results suggest that the most likely water resource impacts are surface water and groundwater contamination from spills at the well pad, which can be as high as 1 in 10 and 1 in 100 for each gas well, respectively. For wells that are hydraulically fractured, the likelihood of contamination due to inter-aquifer leakage is 1 in 10 or lower (dependent on the separation distance between the production formation and the aquifer). For gas-bearing formations that were initially over-pressurized, the potential for contamination from inter-aquifer leakage after production ceases could be as high as 1 in 400 where the separation between gas formation and shallow aquifer is 500 m, but will be much lower for greater separation distances (more characteristic of shale gas).

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Section: Mechanism Methods Of Quantificationmentioning

confidence: 87%

Section: Methods Of Quantificationmentioning

confidence: 99%

Towards Quantifying the Likelihood of Water Resource Impacts from Unconventional Gas Development

2018

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“…However, the large increase in proximity to access roads and well pads is still likely to have impacts on the ecological functioning of prairie potholes. This type of development is likely to cause increases in run-off and sedimentation (Entrekin, Evans-White, Johnson, & Hagenbuch, 2011;Post van der Burg & Tangen, 2015), chemical pollution (from wells, vehicles, and winter road treatments; Amrhein, Strong, & Mosher, 1992;Coffin, 2007;Drapper, Tomlinson, & Williams, 2000;Green, Machin, & Cresser, 2008;Maloney et al, 2017), noise pollution (Kight & Swaddle, 2011), light pollution (Longcore & Rich, 2004), direct animal mortality from traffic (Fahrig & Rytwinski, 2009;Sargeant, 1981), and dust (Farmer, 1993). Even if well pad and road development remains distant enough to have minimal direct impacts on wildlife, animals often exhibit behavioral changes to decreasing development distances (Kociolek, Clevenger, St Clair, & Proppe, 2011).…”

Section: Discussionmentioning

confidence: 99%

Impact of the Bakken/Three Forks unconventional oil and gas development on natural habitats in North Dakota

et al. 2019

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Unconventional oil and gas production (i.e., horizontal drilling and hydrofracturing) has expanded rapidly in the US. One important region where this expansion has occurred is the Bakken/Three Forks Formation, a tight oil play that has made North Dakota a major U.S. oil producer. Using a spatial well database and satellite imagery, we directly measured land‐use changes caused by recent oil and gas activities in two important natural habitats in North Dakota. These two habitats were prairie potholes and public lands that include conservation of wildlife as part of their publicly stated mission. For public lands, we found that about 2,600 ha have been developed, edge habitat increased by almost 30 km (3.65% increase), and average fragment size decreased by 0.70%. Few prairie potholes were directly impacted by this activity, but distance to development decreased for almost one third (434/1,300) by an average of about 400 m. Although land cover changes have been measured in this region in previous publications, our results showing changes in fragmentation, edge habitat, and distance to development provide new metrics for how these habitats in North Dakota are being affected by fossil fuel activity. Observed land‐use changes, while modest, likely have negative impacts on wildlife, including increased mortality or habitat avoidance. Given the potential spread of unconventional oil and gas across the globe, understanding these patterns should help inform land and wildlife managers, as well as the oil and gas industry, about strategies to limit impacts of well and infrastructure placement on valuable wildlife habitats.

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“…Hazards and risks associated with owback and produced water include hazards associated with accidental spills, leaks, and other emissions. [8][9][10][11] Concerns also arise from the potential contamination of surface water and aquifers due to poor well construction or maintenance, disposal of spent uids, and disposal of uids generated during oil and gas production. 7, 12,13 Previous studies have investigated the phenomenon of owback in produced water from stimulated wells and found that water quality of the return-ow changed over time, typically with an initial composition (as indicated by total dissolved solids (TDS) or other chemical indicators) similar to the injected uid, with a gradual transition to more saline connate water.…”

Section: Introductionmentioning

confidence: 99%

Flowback verses first-flush: new information on the geochemistry of produced water from mandatory reporting

Stringfellow

Camarillo

2019

Environ. Sci.: Processes Impacts

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Unconventional oil and gas development uses the subsurface injection of large amounts of a variety of industrial chemicals, and there are concerns about the return of these chemical to the surface with water produced with oil and gas from stimulated wells. Produced water, including any flowback of injected fluids, must be managed so as to protect human health and the environment, and understanding the chemistry of produced water from stimulated wells is necessary to ensure the safe management of produced water. In 2014, California instituted mandatory reporting for all well stimulations, including sampling produced water two times and comprehensive chemical characterization of fluids injected and fluids recovered from stimulated wells. In this study, we analyzed data from mandatory reporting with the objective of closing previously identified data gaps concerning oil-field chemical practices and the nature of flowback and produced water from stimulated wells. It was found that the plug-flow conceptual model of flowback developed in shale formations, where salinity increases over time as produced water is extracted, was not appropriate for characterizing produced water from unconventional wells in these oil reservoirs, which are predominately diatomite and sandstones. In these formations stimulation caused a "first-flush" phenomena, where salts and metals were initially high and then decreased in concentration over time, as more produced water was extracted. Although widely applied to meet regulatory requirements, total carbohydrate measurement was not found to be a good chemical indicator of hydraulic fracturing flowback. Mandatory reporting closed data-gaps concerning chemical use, provided new information on acid treatments, and allowed more detailed analysis of hydraulic fracturing practices, including comparison of water use by geological formation. Environmental signicanceMandatory reporting by industry allowed detailed analysis of hydraulic fracturing practices, including comparison of chemical use and produced water quality by geological formation. The pseudo-plug-ow conceptual model of owback developed in shale formations, where salinity increases over time as produced water is extracted, was not applicable to unconventional wells in these oil reservoirs, which are predominately diatomite and sandstones. In these formations stimulation caused a "rst-ush" phenomena, where salts and metals were initially high and then decreased in concentration over time, as more produced water was extracted. New information on acid treatments and the use of chemical indicators of owback indicate that acid fracturing treatments are infrequently applied and the use of chemical indicators needs to be further validated.

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Unconventional oil and gas spills: Materials, volumes, and risks to surface waters in four states of the U.S.

Cited by 95 publications

References 33 publications

Towards Quantifying the Likelihood of Water Resource Impacts from Unconventional Gas Development

Towards Quantifying the Likelihood of Water Resource Impacts from Unconventional Gas Development

Impact of the Bakken/Three Forks unconventional oil and gas development on natural habitats in North Dakota

Flowback verses first-flush: new information on the geochemistry of produced water from mandatory reporting

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