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AuthorKasha, A.
AuthorMyers, M.
AuthorHathon, L.
AuthorSakhaee-Pour, A.
AuthorSadooni, F.
AuthorNasser, M.
AuthorHussein, I.
AuthorAl-Kuwari, H.A.
Available date2024-08-05T05:08:12Z
Publication Date2023
Publication NameGeoenergy Science and Engineering
ResourceScopus
ISSN29498910
URIhttp://dx.doi.org/10.1016/j.geoen.2023.212245
URIhttp://hdl.handle.net/10576/57424
AbstractClosure correction is a key requirement for a reliable petrophysical evaluation using mercury injection capillary pressure (MICP). The available correction methods rely on identifying deflection points on capillary pressure curves which is often difficult and subjective and requires additional information for macropores that control the closure effect. The proposed approach in this study is novel in terms of integrating the pore-throat size distribution and incremental mercury intrusion data from MICP with porosity from routine core analysis as well as 2D visualization and watershed segmentation from thin section images. The proposed approach allows for lowering the uncertainty in closure correction by incorporating the pore-throat sizes and segmented porosity of the macropores from thin-section images. We tested this approach on samples of the Austin Chalk and Indiana Limestone. The effects of sample size and equilibrium time were also investigated. Identifying the closure pressure is demonstrated to be more difficult on small crushed samples due to the impact of mercury conformance associated with the increased specific surface area. The impact of increasing the equilibrium time is insignificant on relatively permeable Austin Chalk. However, for the tighter Indiana Limestone, conducting fast MICP experiments results in inconsistent and misleading results. We used rate-equilibrium testing at 0.001 μL/g to generate initial-residual curves and evaluate pores accessibility. We show that Austin Chalk pores are fully intruded below 10,000 psia whereas Indiana Limestone requires higher pressure to invade all the pore systems. This study emphasizes the importance of integrating additional information with the MICP data for the closure correction of complex pore systems.
SponsorThe authors would like to acknowledge the support of the Qatar National Research Fund (a member of the Qatar Foundation) through Grants NPRP11S-1228-170138; NPRP12S-0305-190235; and NPRP12S-0130-190023. The findings achieved herein are solely the responsibility of the authors. We would like to acknowledge Jomana Abdel Razik for digitizing the thin sections used in this work.
Languageen
PublisherElsevier
SubjectCapillary pressure
carbonates
Closure correction
Equilibrium time
Mercury injection
Pore-throat size distribution
Sample size
TitleIntegrated approach for closure correction of mercury injection capillary pressure measurements
TypeArticle
Volume Number230
dc.accessType Full Text


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