Revisiting the role of fluid imbibition in the hydrocarbon recovery processes from shale reservoirs

Authors

  • Boyun Guo* College of Engineering, University of Louisiana at Lafayette, Lafayette LA 70504, USA (Email: boyun.guo@louisiana.edu)
  • Philip Wortman College of Engineering, University of Louisiana at Lafayette, Lafayette LA 70504, USA

Abstract

Spontaneous imbibition has recently received a great deal of research attention for improving hydrocarbon recovery from shale gas and oil reservoirs. It is highly desirable to know the true significance and the role of fluid imbibition in the recovery process. Using a Krüss Drop Shape Analyzer 100S with Krüss’ Advance software, water imbibition depth was measured in this study on dry cores from four shale gas/oil reservoirs namely Tuscaloosa Marine Shale, Eagle Fort Shale, Marcellus Shale, and Green River Shale. The initial water-contact angles on the Tuscaloosa Marine Shale, Eagle Fort Shale, Marcellus Shale and Green River Shale core surfaces were measured to be 36.62◦, 66.68◦, 52.78◦ and 84.73◦, respectively. The contact angle and thus volume of liquid droplet changed due to fluid imbibition into the core samples and evaporation. The change in droplet volume, together with the contact area and shale porosity, was used to calculate the imbibition depth. An analytical imbibition model was derived and tuned to upscale the tested fluid imbibition data to field level. The result of time-upscaling using the tuned imbibition models shows that the 1-month water imbibition depths for the Tuscaloosa Marine Shale, Eagle Fort Shale, Marcellus Shale and Green River Shale are 2.61, 1.59, 0.89 and 0.16 cm, respectively. These low values suggest that the direct effect of water imbibition into shale matrix on hydrocarbon recovery in shale reservoirs is insignificant in the practical scales of space and time. However, the imbibition-induced shale cracks can increase shale permeability significantly for mass transfer during the hydrocarbon recovery process. Water imbibition in the cracks should be investigated in future studies.

Document Type: Original article

Cited as: Guo, B., Wortman, P. Revisiting the role of fluid imbibition in the hydrocarbon recovery processes from shale reservoirs. Capillarity, 2025, 15(2): 25-32. https://doi.org/10.46690/capi.2025.05.01

Keywords:

Shale gas and oil, spontaneous imbibition, capillary pressure, mathematical model, experimental investigation

References

Berg, R. R. Method of determining permeability from reservoir rock properties. Transactions of Gulf Coast Association of Geological Societies, 1970, 20: 303-317.

Borrok, D. M., Yang, W., Wei, M., et al. Heterogeneity of the mineralogy and organic content of the Tuscaloosa Marine Shale. Marine and Petroleum Geology, 2019, 109, 717-731.

Burnham, A. K. Porosity and permeability of Green River oil shale and their changes during retorting. Fuel, 2017, 203: 208-213.

Cai, J., Perfect, E., Cheng, C., et al. Generalized modeling of spontaneous imbibition based on Hagen-Poiseuille flow in tortuous capillaries with variably shaped apertures. Langmuir, 2014, 30(18): 5142-5151.

Cai, J., Sun, S., Wang, H. Current advances in capillarity: Theories and applications. Capillarity, 2023, 7(2): 25-31.

Dutta, R., Lee, C., Odumabo, S., et al. Quantification of fracturing fluid migration due to spontaneous imbibition in fractured tight formations. Paper SPE 154939 Presented at the SPE Americas Unconventional Resources Conference, Pittsburgh, Pennsylvania, 5-7 June, 2012.

Finger, L. J., Godet, A., Billingsley, L. T. Porosity evaluation in the Lower Eagle Ford Shale Formation, Atascosa County, South Texas. Gulf Coast Association of Geological Societies Transactions, 2017, 67: 587.

Gao, Z., Fan, Y., Hu, Q., et al. A review of shale wettability characterization using spontaneous imbibition experiments. Marine and Petroleum Geology, 2019, 109: 330-338.

Guo, B., Wortman, P. Understanding the post-frac soaking process in multi-fractured shale gas-oil wells. Capillarity, 2024, 12(1): 6-16.

Handy, L. L. Determination of effective capillary pressures for porous media from imbibition data. Transactions of the AIME, 1960, 219(1): 75-80.

Hu, D., Wu, H., Liu, Z. Effect of liquid-vapor interface area on the evaporation rate of small sessile droplets. International Journal of Thermal Sciences, 2014, 84: 300-308.

Johnson, R. C., Mercier, T. J., Brownfield, M. E., et al. Assessment of in-place oil shale resources of the Green River Formation, Greater Green River Basin in Wyoming, Colorado, and Utah. USA, U.S. Geological Survey, 2011.

Kolodzie Jr., S. Analysis of pore throat size and use of the Waxman-Smits equation to determine OOIP in spindle field, Colorado. Paper SPE 9382 Presented at the SPE Annual Technical Conference and Exhibition, Dallas, 21-24 September 1980.

Li, C., Singh, H., Cai, J. Spontaneous imbibition in shale: A review of recent advances. Capillarity, 2019, 2(2): 17-32.

Lohr, C. D., Hackley, P. C. Using mercury injection pressure analyses to estimate sealing capacity of the Tuscaloosa marine shale in Mississippi, USA: Implications for carbon dioxide sequestration. International Journal of Greenhouse Gas Control, 2018, 78: 375-387.

Lu, J., Milliken, K., Reed, R. M., et al. Diagenesis and sealing capacity of the middle Tuscaloosa mudstone at the Cranfield carbon dioxide injection site, Mississippi, USA. Environmental Geosciences, 2011, 18(1): 35-53.

Lu, J., Ruppel, S. C., Rowe, H. D. Organic matter pores and oil generation in the Tuscaloosa marine shale. AAPG Bulletin, 2015, 99(2): 333-357.

Mahmood, M. H., Nguyen, V., Guo, B. Challenges in mathematical modeling of dynamic mass transfer controlled by capillary and viscous forces in spontaneous fluid imbibition processes. Capillarity, 2024, 11(2): 53-62.

Pittman, E. D. Relationship of porosity and permeability to various parameters derived from mercury injection-capillary pressure curves for sandstone. American Association of Petroleum Geologists Bull, 1992, 76(2): 191-198.

Saidzade, A., Liu, N., Mokhtari, M., et al. Spontaneous imbibition in shales under one-end-open boundary condition: Effect of wettability, porosity, and bedding orientation. Paper Presented at Unconventional Resources Technology Conference, Virtual, 20-22 July, 2020.

Schwartz, D. H. Successful sand control design for high rate oil and water wells. Journal of Petroleum Technology, 1969, 21(9): 1193-1198.

Shaibu, R., Guo, B. The dilemma of soaking a hydraulically fractured horizontal shale well prior to flowback-A decade literature review. Journal of Natural Gas Science and Engineering, 2021, 94: 104084.

Yang, X., Guo, B. Statistical analyses of reservoir and fracturing parameters for a multifractured shale oil reservoir in Mississippi. Energy Science & Engineering, 2020, 8(3): 616-626.

Yang, Y., Wang, S., Feng, Q., et al. Imbibition mechanisms of fracturing fluid in shale oil formation: A review from the multiscale perspective. Energy & Fuels, 2023, 37(14): 9822-9840.

Yuan, X., Yao, Y., Liu, D., et al. Spontaneous imbibition in coal: Experimental and model analysis. Journal of Natural Gas Science and Engineering, 2019, 67: 108-121.

Zamirian, M., Aminian, K., Ameri, S. Measuring Marcellus shale petrophysical properties. Paper SPE 180366 Presented at the SPE Western Regional Meeting, Anchorage, Alaska, USA, 23-26 May, 2016.

Zhang, J., Guo, B., Amponsah, V. N. B. A more rigorous mathematical model for capillary imbibition of CO2 in shale gas formations. Capillarity, 2025, 14(3): 63-71.

Zhang, P., Guo, B., Liu, N. Numerical simulation of CO2 migration into cement sheath of oil/gas wells. Journal of Natural Gas Science and Engineering, 2021, 94: 104085.

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Published

2025-04-28

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Vol. 15 No. 2 (2025): May

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