Stress-Dependent In Situ Gas Permeability in the Eagle Ford Shale

We measured argon gas permeability in three intact and one partially fractured Eagle Ford Shale samples documenting the stress dependence of horizontal (bedding parallel) in situ permeability of intact samples which varies between 1 and 10 nD (1 nD = 0.9869233 × 10 −21  m 2 ), while the permeability...

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Bibliographic Details
Published in:Transport in porous media 2018-05, Vol.123 (1), p.1-20
Main Authors: Bhandari, Athma R., Flemings, Peter B., Hofmann, Ronny, Polito, Peter J.
Format: Article
Language:English
Subjects:
Argon
Civil Engineering
Classical and Continuum Physics
Confining
Dependence
Earth and Environmental Science
Earth Sciences
Fractures
Gas expansion
Geotechnical Engineering & Applied Earth Sciences
Hydrogeology
Hydrology/Water Resources
Industrial Chemistry/Chemical Engineering
Oil shale
Permeability
Shale gas
Stresses
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Summary:We measured argon gas permeability in three intact and one partially fractured Eagle Ford Shale samples documenting the stress dependence of horizontal (bedding parallel) in situ permeability of intact samples which varies between 1 and 10 nD (1 nD = 0.9869233 × 10 −21  m 2 ), while the permeability of partially fractured sample varies between 18 and 37 nD. For all samples, permeability decreases by up to an order of magnitude while cycling the confining pressure ( P C ) between 27.7 and 55.2 MPa at a constant pore pressure ( P P ) of 14.4 MPa. Most of the permeability decrease is within the first loading and unloading cycle. During this first cycle, we also observe less than 2% decline in permeability over ~ 10 days when we held the P C constant at 51.6–55.2 MPa, respectively. This suggests that the ongoing creep plays a relatively minor role. The subsequent P C cycles result in a small decrease in permeability (~ 6 to 26% variation between the start and the end of each cycle). We interpret that the initial permeability loss is due to the closing of micro-fractures—which we infer are caused by stress relief and gas expansion during sample retrieval and/or preparation. We interpret that the higher permeability of the partially fractured sample is mainly due to incomplete closure of a preexisting fracture, which extends nearly two-third the sample length. We document this dual-permeability structure from the observation of a dual-timescale pressure response behavior during the experiments at lower P C – P P . We find permeability decreases with increasing P C – P P ; stress dependency of permeability follows an exponential relationship with a stress-sensitive gradient of 0.019–0.040 MPa −1 . A better understanding of permeability variation with stress will help to reliably estimate in situ permeability and to better understand production evolution from unconventional shale reservoirs.
ISSN:0169-3913
1573-1634
DOI:10.1007/s11242-018-1021-6