Solid Surface Energy of Limestone-H2-Brine Systems: Effect of Organic Acids and Nanofluids

References

1. Akob, D.M., Cozzarelli, I.M., Dunlap, D.S., Rowan, E.L., Lorah, M.M., 2015. Organic and inorganic composition and microbiology of produced waters from Pennsylvania shale gas wells.Applied Geochemistry60, 116–125.
   [Google Scholar]
2. Al-Anssari, S., Arif, M., Wang, S., Barifcani, A., Lebedev, M., Iglauer, S., 2017. Wettability of nano-treated calcite/CO2/brine systems: Implication for enhanced CO2 storage potential.International Journal of Greenhouse Gas Control66, 97–105.
   [Google Scholar]
3. Ali, M., Aftab, A., Arain, Z.-U.-A., Al-Yaseri, A., Roshan, H., Saeedi, A., Iglauer, S., Sarmadivaleh, M., 2020a. Influence of organic acid concentration on wettability alteration of cap-rock: implications for CO2 trapping/storage.ACS Applied Materials & Interfaces12, 39850–39858.
   [Google Scholar]
4. Ali, M., Sahito, M.F., Jha, N.K., Memon, S., Keshavarz, A., Iglauer, S., Saeedi, A., Sarmadivaleh, M., 2020b. Effect of nanofluid on CO2-wettability reversal of sandstone formation; implications for CO2 geo-storage.Journal of colloid and interface science559, 304–312.
   [Google Scholar]
5. Ameri, A., Kaveh, N.S., Rudolph, E., Wolf, K.H., Farajzadeh, R., Bruining, J., 2013. Investigation on interfacial interactions among crude oil–brine–sandstone rock–CO2 by contact angle measurements.Energy and fuels27, 1015–1025.
   [Google Scholar]
6. Arif, M., Barifcani, A., Iglauer, S., 2016. Solid/CO2 and solid/water interfacial tensions as a function of pressure, temperature, salinity and mineral type: Implications for CO2-wettability and CO2 geo-storage.International Journal of Greenhouse Gas Control53, 263–273.
   [Google Scholar]
7. Hosseini, M., Ali, M., Fahimpour, J., Keshavarz, A., Iglauer, S., 2022a. Assessment of rock-hydrogen and rock-water interfacial tension in shale, evaporite and basaltic rocks.Journal of Natural Gas Science & Engineering, 104743.
   [Google Scholar]
8. Hosseini, M., Ali, M., Fahimpour, J., Keshavarz, A., Iglauer, S., 2023. Calcite–Fluid Interfacial Tension: H2 and CO2 Geological Storage in Carbonates.Energy & Fuels.
   [Google Scholar]
9. Hosseini, M., Fahimpour, J., Ali, M., Keshavarz, A., Iglauer, S., 2022b. Hydrogen wettability of carbonate formations: Implications for hydrogen geo-storage.Journal of Colloid & Interface Science614, 256–266.
   [Google Scholar]
10. Kvenvolden, K.A., 1967. Normal fatty acids in sediments.Journal of the American Oil Chemists’ Society44, 628–636.
    [Google Scholar]
11. Owens, J., 2009. Indiana Limestone Handbook, Indiana Limestone Institute of America. Inc.
    [Google Scholar]
12. Pan, B., Yin, X., Iglauer, S., 2021. Rock-fluid interfacial tension at subsurface conditions: Implications for H2, CO2 and natural gas geo-storage.International Journal of Hydrogen Energy46, 25578–25585.
    [Google Scholar]
13. Tadmor, R., 2004. Line energy and the relation between advancing, receding, and young contact angles.Langmuir20, 7659–7664.
    [Google Scholar]
14. Young, T., 1805. III. An essay on the cohesion of fluids.Philosophical transactions of the royal society of London, 65–87.
    [Google Scholar]
15. Zivar, D., Kumar, S., Foroozesh, J., 2021. Underground hydrogen storage: A comprehensive review.International Journal of Hydrogen Energy46, 23436–23462.
    [Google Scholar]