Geomechanical simulation to predict open subsurface fractures

Lewis, Helen; Hall, Stephen A.; Couples, Gary Douglas

doi:10.1111/j.1365-2478.2009.00786.x

Cited by 6 publications

(4 citation statements)

References 38 publications

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“…Fracture height has been recognized as one of the critical factors which can determine the success or failure of a hydraulic fracturing treatment. Many studies have been conducted for the effects of in-situ stresses, formation Young's modulus, fracture toughness and layer interfacial slip on hydraulic fracture height containment in layered formations (van Eekelen, 1982;Teufel and Clark, 1984;Thiercelin et al, 1987;Wang and Clifton, 1990;Warpinski et al, 1982Warpinski et al, , 1998Smith et al, 2001;Gu and Siebrits, 2006;Gu et al, 2008;Daneshy, 2009;Iyer and Podladchikov, 2009;Lewis et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Three-dimensional finite element simulation and parametric study for horizontal well hydraulic fracture

Zhang

Liu

Zhang

et al. 2010

Journal of Petroleum Science and Engineering

121

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Section: Introductionmentioning

confidence: 99%

Three-dimensional finite element simulation and parametric study for horizontal well hydraulic fracture

Zhang

Liu

Zhang

et al. 2010

Journal of Petroleum Science and Engineering

121

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“…We follow Lewis et al (2009) and use effective plastic strain and volumetric strain to predict the opening of fractures. Von Mises effective plastic strain distribution in the model at 10.4 kyears is shown in Fig.…”

Section: Plastic Deformation and Volumetric Strainmentioning

confidence: 99%

Fracture formation due to differential compaction under glacial load: a poro-elastoplastic simulation of the Hugin Fracture

Landschulze

2021

Mar Geophys Res

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The Hugin Fracture, discovered in 2011, is an approximately 3.5 km long seafloor fracture in the North Sea. This fracture was unexpected and, due to the geology in the North Sea no obvious explanation could be found. In our study, we adopt the hypothesis that the Hugin fracture was formed by differential compaction controlled by glacial load. We construct a simplified 2D geomechanical model partly covered by top load (ice sheet) and test this hypothesis. We employ transient poro-elastoplastic simulation with a finite element method. For the simulations, we had to make assumptions regarding the material properties, because the fracture is located in-between well locations. We used descriptions from drilling site survey reports and literature values and performed seismic matching form well paths to the Hugin Fracture. Nearby well data were only partly useful due to incomplete logging in the first 400 m below seafloor. To overcome this problem, we introduced a mixing k-value which allows us to easily change the material properties from pure clay to sand. Changing the mixing k-value for each simulation provided information about the limits and robustness of the simulation results. Simulation results show isotropic stress and strain distribution in the horizontally layered, isotropic part of the model that is totally covered by the ice. In the central, channelized part of the model a composite stress and strain pattern develops with sub-vertical focus areas tangential to channel edges. Low stress, strain and deformation values under total load increase drastically soon after the load starts to decrease, resulting in the development of fractures along the focussed zones. Surface deformation such as formation of compaction ridges above stiff clay-filled channels and depression associated with plastic deformation is observed. A fracture and associated surface deformation develop above the shallowest sand-filled channel, very much resembling the observed geometry at the Hugin Fracture. The simulation supports the formation hypothesis for the Hugin Fracture as a compaction fracture and suggests that thin ice sheets may induce differential compaction to a depth of several hundred meters.

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“…Laboratory studies play key roles in developing that understanding for both the geomaterial framework [15] and the contained fluids [16,17]. Laboratory studies also support the derivation of behavioural laws that underpin numerical simulations of the subsurface [18,19], to performing the numerical simulations themselves and thus provide understanding of unseen processes [20]. A large body of work already provides general understanding and associated laws.…”

Section: Introductionmentioning

confidence: 99%

Dynamic Fluid Ingress Detection in Geomaterials Using K-Band Frequency Modulated Continuous Wave Radar

et al. 2020

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Frequency modulated continuous wave (FMCW) radar in the K-band has been shown to be an effective detector of geomaterial physical properties being highly sensitive to rock characteristics, particularly mineral composition and, for porous rock, variations in liquid water content. This research demonstrates that contrasts in FMCW return signals with time correlate with changes in geomaterial water content. FMCW signal returns were acquired for porous sandstone samples subjected to controlled water injection while also in a neutron beam, taking advantage of the well-known, and wellcalibrated, attenuation of neutrons by hydrogen atoms for the water-containing porous sandstone samples. The sequential neutron tomographic images clearly show water moving up the sample with time while the FMCW observations show increases in radar reflection coefficient as a function of water position in the field of view. The observed FMCW detection of flood-front position is corroborated by the synchronous neutron tomographic images. We also observe repeatable variations in the radar reflection coefficient as a function of sample orientation during fluid injection, verifying that FMCW sensing offers real-time insight into the interactions between fluid movement and sample heterogeneity, via non-contact and noninvasive flood-front tracking. This research demonstrates that FMCW has potential to be a more accessible and easily deployable sensing modality than neutron tomography, enabling dynamic geomaterial testing to be conducted outwith the confines of the highly controlled laboratory environment required for neutron investigation.

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Geomechanical simulation to predict open subsurface fractures

Cited by 6 publications

References 38 publications

Three-dimensional finite element simulation and parametric study for horizontal well hydraulic fracture

Three-dimensional finite element simulation and parametric study for horizontal well hydraulic fracture

Fracture formation due to differential compaction under glacial load: a poro-elastoplastic simulation of the Hugin Fracture

Dynamic Fluid Ingress Detection in Geomaterials Using K-Band Frequency Modulated Continuous Wave Radar

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