The impacts of effective stress and CO^sub 2^ sorption on the matrix permeability of shale reservoir rocks

We assess the impacts of effective stress and CO2 sorption on the bedding-parallel matrix permeability of the Utica shale through pressure pulse-decay experiments. We first measure permeability using argon at relatively high (14.6 MPa) and low (2.8 MPa) effective stresses to assess both pressure dep...

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Bibliographic Details
Published in:Fuel (Guildford) 2017-09, Vol.203, p.179
Main Authors: Wu, Wei, Zoback, Mark D, Kohli, Arjun H
Format: Article
Language:English
Subjects:
Argon
Bedding
Carbon dioxide
Computational fluid dynamics
Fluid flow
Permeability
Porosity
Pressure
Pressure dependence
Recoverability
Reduction
Reservoirs
Rocks
Shale
Sorption
Stress
Stresses
Studies
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Summary:We assess the impacts of effective stress and CO2 sorption on the bedding-parallel matrix permeability of the Utica shale through pressure pulse-decay experiments. We first measure permeability using argon at relatively high (14.6 MPa) and low (2.8 MPa) effective stresses to assess both pressure dependence and recoverability. We subsequently measure permeability using supercritical CO2 and again using argon to assess changes due to CO2 sorption. We find that injection of both argon and supercritical CO2 reduces matrix permeability in distinct fashion. Samples with permeability higher than 10-20 m2 experience a large permeability reduction after treatment with argon, but a minor change alter treatment with super- critical CO2. However, samples with permeability lower than this threshold undergo a slight change after treatment with argon, but a dramatic reduction after treatment with supercritical CO2. These results indicate that effective stress plays an important role in the evolution of relatively permeable facies, while CO2 sorption dominates the change of ultra-low permeability fades. The permeability reduction due to CO2 sorption varies inversely with initial permeability, which suggests that increased surface area from hydraulic stimulation with CO2 may be counteracted by sorption effects in ultra-low permeability facies. We develop a conceptual model to explain how CO2 sorption induces porosity reduction and volumetric expansion to constrict fluid flow pathways in shale reservoir rocks.
ISSN:0016-2361
1873-7153