On the Thermo-Hydro-Mechanical Behaviour of a Sheared Callovo-Oxfordian Claystone Sample with Respect to the EDZ Behaviour

Menaceur, Hamza; Delage, Pierre; Tang, Anh Minh; Conil, Nathalie

doi:10.1007/s00603-015-0897-5

Cited by 35 publications

(30 citation statements)

References 34 publications

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“…Substantially fewer studies have used shale, which can exhibit very low permeability and high ductility behavior due to clay content [e.g., Gutierrez et al ., ]. These prefractured specimen experiments contrast with the more limited studies of permeability through fractures that are formed at under high stress conditions, which have included true‐triaxially confined granite [ Frash et al ., , ] and triaxially confined shale [ Carey et al ., , ; Menaceur et al ., ; Nygard et al ., ]. Laboratory study of permeability through fractures formed in rock at in situ stresses can be expected to better represent fracture properties in the subsurface than similar studies using prefractured or artificial specimens.…”

Section: Introductionmentioning

confidence: 98%

High‐stress triaxial direct‐shear fracturing of Utica shale and in situ X‐ray microtomography with permeability measurement

et al. 2016

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The challenge of characterizing subsurface fluid flow has motivated extensive laboratory studies, yet fluid flow through rock specimens in which fractures are created and maintained at high‐stress conditions remains underinvestigated at this time. The studies of this type that do exist do not include in situ fracture geometry measurements acquired at stressed conditions, which would be beneficial for interpreting the flow behavior. Therefore, this study investigates the apparent permeability induced by direct‐shear fracture stimulation through Utica shale (a shale gas resource and potential caprock material) at high triaxial stress confinement and for the first time relates these values to simultaneously acquired in situ X‐ray radiography and microtomography images. Change in fracture geometry and apparent permeability was also investigated at additional reduced stress states. Finite element and combined finite‐discrete element modeling were used to evaluate the in situ observed fracturing process. Results from this study indicate that the increase in apparent permeability through fractures created at high‐stress (22.2 MPa) was minimal relative to the intact rock (less than 1 order of magnitude increase), while fractures created at low stress (3.4 MPa) were significantly more permeable (2 to 4 orders of magnitude increase). This study demonstrates the benefit of in situ X‐ray observation coupled with apparent permeability measurement to analyze fracture creation in the subsurface. Our results show that the permeability induced by fractures through shale at high stress can be minor and therefore favorable in application to CO2 sequestration caprock integrity but unfavorable for hydrocarbon recovery from unconventional reservoirs.

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Section: Introductionmentioning

confidence: 98%

High‐stress triaxial direct‐shear fracturing of Utica shale and in situ X‐ray microtomography with permeability measurement

et al. 2016

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“…The satisfactory results obtained with these calculations at a rate of 6.6×10 -8 s -1 are comparable with the values of strain rate adopted in claystones and shales by Wu et al (1997) and Islam and Skalle (2013), equal to 3×10 -8 s -1 and 2×10 -8 s -1 , respectively. They are around two orders of magnitude smaller than those used by Zhang and Rothfuchs (2004) and Masri et al (2014) (6.5×10 -6 s -1 and 1.0×10 -6 s -1 , respectively) and approximately correspond to half the values adopted by Hu et al (2015) and Menaceur et al (2016a) on devices with smaller drainage lengths (1.0×10 -7 s -1 and 0.9×10 -7 s -1 with a 10 mm drainage length) .…”

Section: Drained Shear Ratementioning

confidence: 56%

“…This small drainage length, four times smaller than standard triaxial drainage length (38 mm), reduces the pore pressure diffusion rate by a factor of 16 compared to standard triaxial specimens (Monfared et al, 2011). As shown by Monfared et al (2011), Mohajerani et al (2013), Menaceur et al (2015) and Menaceur et al (2016a) with hollow cylinder specimen and by Hu et al (2014) with small-sized specimen, the 10 mm drainage length made it possible to achieve satisfactory saturation within 3 to 4 days, compared to a period of around one month in standard triaxial tests. Reasonable results of fully saturated and drained isotropic compression tests have also been obtained for the COx claystone with a 10 mm high specimen drained at the bottom, also resulting in a 10 mm drainage length (Mohajerani et al 2012;Belmokhtar et al 2017aBelmokhtar et al , 2017b.…”

Section: As Stated Bymentioning

confidence: 87%

Drained Triaxial Tests in Low-Permeability Shales: Application to the Callovo-Oxfordian Claystone

et al. 2018

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Drained triaxial testing is challenging in low permeability claystones (10-20 m 2). This paper presents a method of testing low permeability clay rocks in a standard triaxial cell. In this system, the resaturation of the specimen and the drainage conditions were enhanced by reducing the drainage length to 19 mm, the specimen radius. To do so, two geotextiles were placed around the top and bottom ends of the specimen, with no connection between them. Resaturation was hence performed by forcing water infiltration into the specimen from the upper and lower geotextiles, with a maximum infiltration length of around 19 mm, resulting in reasonable saturation durations. High precision local measurements of radial strains were also achieved by ensuring direct contact between the LVDT rod and the specimen through the membrane. A poroelastic numerical calculation was carried out, and it was shown that, with these drainage conditions, a strain rate of 6.6×10-8 s-1 was satisfactory to ensure good drainage when shearing claystone specimens. After a check test made on a low permeability sandstone with well-known mechanical characteristics, two tests were carried out to investigate specimens of the Callovo-Oxfordian claystone, a possible host rock for deep geological disposal in France. The results compare well with other published data from drained triaxial tests.

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“…The Callovo-Oxfordian claystone is a sedimentary rock deposited 155 million years ago over a layer of Dogger limestone in a 150 m thick layer covered by a layer of Oxfordian 5 limestone. The COx claystone has a very low permeability in the order of 10 -20 m 2 (see Escoffier 2005, Homand et al 2004, Escoffier et al 2005, Mohajerani et al 2011, Menaceur et al 2015a), a high adsorption capacity for radionuclides and a low diffusion coefficient delaying solute transfer. For all these reasons, it has been considered as a potential host rock to store high activity radioactive waste at great depth in France.…”

Section: The Callovo-oxfordian Claystonementioning

confidence: 99%

“…Mohajerani et al 2011) and excellent self-sealing capacity of the COx claystone (e.g. Davy et al 2007;Zhang and Rothfuchs 2008;Menaceur et al 2015a).…”

Section: The Callovo-oxfordian Claystonementioning

confidence: 99%

Active porosity in swelling shales: insight from the Callovo-Oxfordian claystone

Belmokhtar

Delage

Ghabezloo

et al. 2018

Géotechnique Letters

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In swelling claystones, significant clay-water interactions take place along the faces of the smectites minerals contained in the clay fraction, giving rise to the distinction between free water and adsorbed water. Further insight was recently gained by means of microstructure investigations, showing that the hydration mechanisms of pure or compacted smectites also hold to explain the hydration and swelling behaviour of the Callovo-Oxfordian (COx) claystone, a possible host rock for deep radioactive waste disposal in France. In this rock, the proportion of water molecules adsorbed in intra-platelets pores was recently estimated to around 25% of the total porosity, with 75% of the porosity containing free water. Based on these findings, the data of high precision poroelastic measurements conducted in an isotropic compression cell showed that the porosity to account for a proper calculation of the Skempton parameter is not the total porosity, but the 75% proportion corresponding to free water. This conclusion is believed to be of some interest with respect to the prediction of the rock response around the disposals at great depth, given that hydromechanical numerical simulations are often carried out within the framework of poroelasticity.

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On the Thermo-Hydro-Mechanical Behaviour of a Sheared Callovo-Oxfordian Claystone Sample with Respect to the EDZ Behaviour

Cited by 35 publications

References 34 publications

High‐stress triaxial direct‐shear fracturing of Utica shale and in situ X‐ray microtomography with permeability measurement

High‐stress triaxial direct‐shear fracturing of Utica shale and in situ X‐ray microtomography with permeability measurement

Drained Triaxial Tests in Low-Permeability Shales: Application to the Callovo-Oxfordian Claystone

Active porosity in swelling shales: insight from the Callovo-Oxfordian claystone

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