Numerical modeling of fracking fluid migration through fault zones and fractures in the North German Basin

Pfunt, Helena; Houben, Georg; Himmelsbach, Thomas

doi:10.1007/s10040-016-1418-7

Cited by 21 publications

(12 citation statements)

References 32 publications

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“…These results indicate that high hydraulic conductivity formations in the deep subsurface, but beyond the induced fracture extent, can be more effective barriers to upward fluid migration than low hydraulic conductivity formations. Numerical modeling of the North German Basin also showed horizontal fluid transport in more hydraulically conductive formations above the modeled fluid injection (Pfunt et al, ), suggesting that this protective mechanism is not unique to the proposed site.…”

Section: Discussionmentioning

confidence: 93%

“…Their worst‐case scenario, with fractures directly connecting the fracked shale to the shallow aquifer, resulted in aquifer contamination in 100 years. Further, Palat et al () and Pfunt et al () investigated the effects of faults on fracking fluid migration using models of the North Perth Basin (Australia) and the North German Basin (Germany), respectively. Neither study observed fracking fluids reaching the regional aquifers within the simulated timescales of 20 and 300 years, respectively.…”

Section: Introductionmentioning

confidence: 99%

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Shallow Aquifer Vulnerability From Subsurface Fluid Injection at a Proposed Shale Gas Hydraulic Fracturing Site

Wilson

Worrall

Davies

et al. 2017

Water Resources Research

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Groundwater flow resulting from a proposed hydraulic fracturing (fracking) operation was numerically modeled using 91 scenarios. Scenarios were chosen to be a combination of hydrogeological factors that a priori would control the long‐term migration of fracking fluids to the shallow subsurface. These factors were induced fracture extent, cross‐basin groundwater flow, deep low hydraulic conductivity strata, deep high hydraulic conductivity strata, fault hydraulic conductivity, and overpressure. The study considered the Bowland Basin, northwest England, with fracking of the Bowland Shale at ∼2,000 m depth and the shallow aquifer being the Sherwood Sandstone at ∼300–500 m depth. Of the 91 scenarios, 73 scenarios resulted in tracked particles not reaching the shallow aquifer within 10,000 years and 18 resulted in travel times less than 10,000 years. Four factors proved to have a statistically significant impact on reducing travel time to the aquifer: increased induced fracture extent, absence of deep high hydraulic conductivity strata, relatively low fault hydraulic conductivity, and magnitude of overpressure. Modeling suggests that high hydraulic conductivity formations can be more effective barriers to vertical flow than low hydraulic conductivity formations. Furthermore, low hydraulic conductivity faults can result in subsurface pressure compartmentalization, reducing horizontal groundwater flow, and encouraging vertical fluid migration. The modeled worst‐case scenario, using unlikely geology and induced fracture lengths, maximum values for strata hydraulic conductivity and with conservative tracer behavior had a particle travel time of 130 years to the base of the shallow aquifer. This study has identified hydrogeological factors which lead to aquifer vulnerability from shale exploitation.

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Section: Discussionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Shallow Aquifer Vulnerability From Subsurface Fluid Injection at a Proposed Shale Gas Hydraulic Fracturing Site

Wilson

Worrall

Davies

et al. 2017

Water Resources Research

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“…Modeling the impact of a potential shale gas industry in Germany and the United Kingdom on ozone with WRF-Chem have been published on European shale gas and for the UK and Germany in particular, e.g., ACATECH (2016), AQEG (2018), BGR (2012), Broomfield et al (2014); Cotton et al (2014), DECC (2013), DECC (2014), Hays et al (2015), McGlade et al (2014), MULNV NRW (2012), Pfunt (2016), Sauter et al (2013), SGD (2013), Society (2012) SRU (2013), Stamford and Azapagic (2014), UBA (2013UBA ( , 2014.…”

Section: Research Articlementioning

confidence: 99%

Modeling the impact of a potential shale gas industry in Germany and the United Kingdom on ozone with WRF-Chem

Weger

Lupaşcu

Cremonese

et al. 2019

Elementa: Science of the Anthropocene

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Germany and the United Kingdom have domestic shale gas reserves which they may exploit in the future to complement their national energy strategies. However gas production releases volatile organic compounds (VOC) and nitrogen oxides (NO x ), which through photochemical reaction form ground-level ozone, an air pollutant that can trigger adverse health effects e.g. on the respiratory system. This study explores the range of impacts of a potential shale gas industry in these two countries on local and regional ambient ozone. To this end, comprehensive emission scenarios are used as the basis for input to an onlinecoupled regional chemistry transport model (WRF-Chem). Here we simulate shale gas scenarios over summer (June, July, August) 2011, exploring the effects of varying VOC emissions, gas speciation, and concentration of NO x emissions over space and time, on ozone formation. An evaluation of the model setup is performed, which exhibited the model's ability to predict surface meteorological and chemical variables well compared with observations, and consistent with other studies. When different shale gas scenarios were employed, the results show a peak increase in maximum daily 8-hour average ozone from 3.7 to 28.3 μg m -3 . In addition, we find that shale gas emissions can force ozone exceedances at a considerable percentage of regulatory measurement stations locally (up to 21% in Germany and 35% in the United Kingdom) and in distant countries through long-range transport, and increase the cumulative healthrelated metric SOMO35 (maximum percent increase of ~28%) throughout the region. Findings indicate that VOC emissions are important for ozone enhancement, and to a lesser extent NO x , meaning that VOC regulation for a future European shale gas industry will be of especial importance to mitigate unfavorable health outcomes. Overall our findings demonstrate that shale gas production in Europe can worsen ozone air quality on both the local and regional scales.

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“…The presence of low-permeability overburden rocks [4,18], production from the horizontal well [11,13,17], fracturing fluid imbibition into the shale reservoir [19,20], and mixing or other dilution processes during the transport [17,21] limit the vertical extent of fracturing fluid, thus reducing the contamination threat to shallow groundwater. Osborn et al [22] analyzed water samples from water wells in aquifers overlying northeastern Pennsylvania (active HF region) and New York (HF is currently not allowed).…”

Section: Introductionmentioning

confidence: 99%

Nonlinear Autoregressive Neural Networks to Predict Hydraulic Fracturing Fluid Leakage into Shallow Groundwater

Taherdangkoo

Tatomir

Taherdangkoo

et al. 2020

Water

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Hydraulic fracturing of horizontal wells is an essential technology for the exploitation of unconventional resources, but led to environmental concerns. Fracturing fluid upward migration from deep gas reservoirs along abandoned wells may pose contamination threats to shallow groundwater. This study describes the novel application of a nonlinear autoregressive (NAR) neural network to estimate fracturing fluid flow rate to shallow aquifers in the presence of an abandoned well. The NAR network is trained using the Levenberg–Marquardt (LM) and Bayesian Regularization (BR) algorithms and the results were compared to identify the optimal network architecture. For NAR-LM model, the coefficient of determination (R2) between measured and predicted values is 0.923 and the mean squared error (MSE) is 4.2 × 10−4, and the values of R2 = 0.944 and MSE = 2.4 × 10−4 were obtained for the NAR-BR model. The results indicate the robustness and compatibility of NAR-LM and NAR-BR models in predicting fracturing fluid flow rate to shallow aquifers. This study shows that NAR neural networks can be useful and hold considerable potential for assessing the groundwater impacts of unconventional gas development.

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Numerical modeling of fracking fluid migration through fault zones and fractures in the North German Basin

Cited by 21 publications

References 32 publications

Shallow Aquifer Vulnerability From Subsurface Fluid Injection at a Proposed Shale Gas Hydraulic Fracturing Site

Shallow Aquifer Vulnerability From Subsurface Fluid Injection at a Proposed Shale Gas Hydraulic Fracturing Site

Modeling the impact of a potential shale gas industry in Germany and the United Kingdom on ozone with WRF-Chem

Nonlinear Autoregressive Neural Networks to Predict Hydraulic Fracturing Fluid Leakage into Shallow Groundwater

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