Numerical assessment of potential impacts of hydraulically fractured <scp>B</scp>owland <scp>S</scp>hale on overlying aquifers

Cai, Zuansi; Ofterdinger, Ulrich

doi:10.1002/2013wr014943

Cited by 34 publications

(40 citation statements)

References 39 publications

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“…Thus, we 10 −16 to 10 −9 (Gassiat et al 2013;Cai and Ofterdinger 2014) 10 −10 to 10 −11 (Miskimins 2008) anticipate, and indeed expect, that future work will build upon this and other similar frameworks, as new data and understanding comes to light. This is imperative for improving scientific, technical, and engineering understanding and practice, regulation, public education, as well as to direct future research.…”

Section: Introductionmentioning

confidence: 76%

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: Introductionmentioning

confidence: 76%

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

2018

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“…Pressure evolution over time for HVHF wells based on numbers from Shapiro and Dinske (), Cai and Ofterdinger (), Edwards and Celia (), and EOR/SWD wells based on Atkinson et al (), IHS Energy (), Oklahoma Corporation Commission (), and Peterie et al ().…”

Section: Evolution Of Reservoir Pressuresmentioning

confidence: 99%

Conventional Oil—The Forgotten Part of the Water‐Energy Nexus

McIntosh¹,

Ferguson

2019

Groundwater

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The impacts of unconventional oil and gas production via high‐volume hydraulic fracturing (HVHF) on water resources, such as water use, groundwater and surface water contamination, and disposal of produced waters, have received a great deal of attention over the past decade. Conventional oil and gas production (e.g., enhanced oil recovery [EOR]), which has been occurring for more than a century in some areas of North America, shares the same environmental concerns, but has received comparatively little attention. Here, we compare the amount of produced water versus saltwater disposal (SWD) and injection for EOR in several prolific hydrocarbon producing regions in the United States and Canada. The total volume of saline and fresh to brackish water injected into depleted oil fields and nonproductive formations is greater than the total volume of produced waters in most regions. The addition of fresh to brackish “makeup” water for EOR may account for the net gain of subsurface water. The total amount of water injected and produced for conventional oil and gas production is greater than that associated with HVHF and unconventional oil and gas production by well over a factor of 10. Reservoir pressure increases from EOR and SWD wells are low compared to injection of fluids for HVHF, however, the longer duration of injections could allow for greater solute transport distances and potential for contamination. Attention should be refocused from the subsurface environmental impacts of HVHF to the oil and gas industry as a whole.

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“…It is well-understood that exploitation of the gas by means of hydraulic fracturing technology would be irresponsible at depths less than roughly 500 m below the surface, since this would entail potentially harvesting the gas within the depth of the natural potable, meteoric water-derived reservoirs of the Karoo. In addition, lithostatic pressures (rock overburden) above even 1 -1.5 km below the surface may not be sufficient to eliminate induced connectivity between the hydraulically stimulated shale gas reservoirs and the shallow water reservoirs, because fractures generated during hydraulic fracturing may extend upwards from the shale reservoir by up to 300 -600 m, albeit generally much less, especially at shallow fracking levels (Maxwell, 2011;Fisher, 2014;Cai and Ofterdinger, 2014). Therefore, those regions where gas-shales occur at less than 1 -1.5 km depth below surface, and even if rich, should be avoided, at least until fracking and casing technologies improve.…”

Section: Towards a Rigorous Scientific Exploration Programme For Gas-mentioning

confidence: 99%

South Africa’s Technical Readiness to Support the Shale Gas Industry

2016

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Numerical assessment of potential impacts of hydraulically fractured Bowland Shale on overlying aquifers

Cited by 34 publications

References 39 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

Conventional Oil—The Forgotten Part of the Water‐Energy Nexus

South Africa’s Technical Readiness to Support the Shale Gas Industry

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