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The Impact of Wetting-Heterogeneity Distribution on Capillary Pressure and Macroscopic Measures of Wettability

Publication ,  Journal Article
Hiller, T; Ardevol-Murison, J; Muggeridge, A; Schröter, M; Brinkmann, M
Published in: SPE Journal
February 13, 2019

We investigate the effect of the length scale of wetting heterogeneities, close to the length scale of a pore, on capillary pressure saturation (CPS) curves and the United States Bureau of Mines (USBM) and Amott-Harvey (AH) wettability indices. These macroscopic wettability indices are used to describe bulk rock wettability, because the local contact angle (the standard physical measure of wettability) in a sample is difficult to access and might vary within and between pores caused by changes in mineralogy and the surface coverage of organic materials. Our study combines laboratory experiments and full-scale fluid-dynamics simulations using the multiphase stochastic-rotation dynamics (SRDmc) model. Four model systems were created using monodisperse glass beads. The surface properties of the beads were modified so that one-half of the surface area in each system was strongly hydrophilic and the other half was hydrophobic. However, each system had a different length scale of wetting heterogeneity, ranging from a fraction of a bead diameter to two bead diameters. There is excellent agreement between the experimental and simulation results. All systems are classified as intermediate-wet on the basis of their AH and USBM indices. An examination of the capillary pressure curves shows that the opening of the stable hysteresis loop decreases monotonically as the length scale of the wetting heterogeneities is increased. Thus, our results suggest that macroscopic wettability indices could be used as indicators of ultimate recovery, but they are not suited to discriminate between the different flows that occur earlier in a mixed-wettability displacement process.

Duke Scholars

Published In

SPE Journal

DOI

EISSN

1930-0220

ISSN

1086-055X

Publication Date

February 13, 2019

Volume

24

Issue

01

Start / End Page

200 / 214

Publisher

Society of Petroleum Engineers (SPE)

Related Subject Headings

  • Energy
  • 4019 Resources engineering and extractive metallurgy
  • 0914 Resources Engineering and Extractive Metallurgy
  • 0404 Geophysics
  • 0403 Geology
 

Citation

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ICMJE
MLA
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Hiller, T., Ardevol-Murison, J., Muggeridge, A., Schröter, M., & Brinkmann, M. (2019). The Impact of Wetting-Heterogeneity Distribution on Capillary Pressure and Macroscopic Measures of Wettability. SPE Journal, 24(01), 200–214. https://doi.org/10.2118/194191-pa
Hiller, Thomas, Julie Ardevol-Murison, Ann Muggeridge, Matthias Schröter, and Martin Brinkmann. “The Impact of Wetting-Heterogeneity Distribution on Capillary Pressure and Macroscopic Measures of Wettability.” SPE Journal 24, no. 01 (February 13, 2019): 200–214. https://doi.org/10.2118/194191-pa.
Hiller T, Ardevol-Murison J, Muggeridge A, Schröter M, Brinkmann M. The Impact of Wetting-Heterogeneity Distribution on Capillary Pressure and Macroscopic Measures of Wettability. SPE Journal. 2019 Feb 13;24(01):200–14.
Hiller, Thomas, et al. “The Impact of Wetting-Heterogeneity Distribution on Capillary Pressure and Macroscopic Measures of Wettability.” SPE Journal, vol. 24, no. 01, Society of Petroleum Engineers (SPE), Feb. 2019, pp. 200–14. Crossref, doi:10.2118/194191-pa.
Hiller T, Ardevol-Murison J, Muggeridge A, Schröter M, Brinkmann M. The Impact of Wetting-Heterogeneity Distribution on Capillary Pressure and Macroscopic Measures of Wettability. SPE Journal. Society of Petroleum Engineers (SPE); 2019 Feb 13;24(01):200–214.

Published In

SPE Journal

DOI

EISSN

1930-0220

ISSN

1086-055X

Publication Date

February 13, 2019

Volume

24

Issue

01

Start / End Page

200 / 214

Publisher

Society of Petroleum Engineers (SPE)

Related Subject Headings

  • Energy
  • 4019 Resources engineering and extractive metallurgy
  • 0914 Resources Engineering and Extractive Metallurgy
  • 0404 Geophysics
  • 0403 Geology