<p>Millions of tons of CO<sub>2</sub> are stored annually in geological formations in order to reduce greenhouse gas emissions, relying on caprock as a seal to prevent CO<sub>2</sub> leakage. The wettability of caprock is crucial for its effectiveness, and can be altered by organic acids present in the storage media. The present study investigates the impact of stearic acid on the CO<sub>2</sub> wettability of shale, along with the potential of alumina nanofluids to reverse this effect. Using contact angle measurements, X-ray diffraction, and other analytical methods, the study reveals that stearic acid increases the CO<sub>2</sub> wettability of shale, making it more difficult to contain CO<sub>2</sub> at higher pressures. Specifically, stearic acid-aged shale samples became CO<sub>2</sub>-wet at 16&#xa0;MPa, thus leading to lower capillary entry pressure and reduced containment capability. However, treatment with alumina nanofluids improves the wettability of shale to intermediate levels, with a 0.25 wt% concentration yielding optimal results. This adjustment also results in positive CO<sub>2</sub> column heights, thus suggesting better containment. The findings demonstrate that alumina nanofluids can enhance CO<sub>2</sub> storage in caprocks by improving the wettability, thus offering a promising approach to the optimization of geological storage solutions for sustainable energy transitions.</p>

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Nanofluid-assisted enhanced sealing containment of caprocks for efficient geological CO2 storage

  • Muhammad Ali,
  • Nurudeen Yekeen,
  • Mujahid Ali,
  • Nilanjan Pal,
  • Mohammed Al Kobaisi,
  • Alireza Keshavarz,
  • Hussein Hoteit

摘要

Millions of tons of CO2 are stored annually in geological formations in order to reduce greenhouse gas emissions, relying on caprock as a seal to prevent CO2 leakage. The wettability of caprock is crucial for its effectiveness, and can be altered by organic acids present in the storage media. The present study investigates the impact of stearic acid on the CO2 wettability of shale, along with the potential of alumina nanofluids to reverse this effect. Using contact angle measurements, X-ray diffraction, and other analytical methods, the study reveals that stearic acid increases the CO2 wettability of shale, making it more difficult to contain CO2 at higher pressures. Specifically, stearic acid-aged shale samples became CO2-wet at 16 MPa, thus leading to lower capillary entry pressure and reduced containment capability. However, treatment with alumina nanofluids improves the wettability of shale to intermediate levels, with a 0.25 wt% concentration yielding optimal results. This adjustment also results in positive CO2 column heights, thus suggesting better containment. The findings demonstrate that alumina nanofluids can enhance CO2 storage in caprocks by improving the wettability, thus offering a promising approach to the optimization of geological storage solutions for sustainable energy transitions.