Ahmed Barifcani scite author profile

Changing oil-wet surfaces toward higher water wettability is of key importance in subsurface engineering applications. This includes petroleum recovery from fractured limestone reservoirs, which are typically mixed or oil-wet, resulting in poor productivity as conventional waterflooding techniques are inefficient. A wettability change toward more water-wet would significantly improve oil displacement efficiency, and thus productivity. Another area where such a wettability shift would be highly beneficial is carbon geo-sequestration, where compressed CO2 is pumped underground for storage. It has recently been identified that more water-wet formations can store more CO2. We thus examined how silica based nanofluids can induce such a wettability shift on oil-wet and mixed-wet calcite substrates. We found that silica nanoparticles have an ability to alter the wettability of such calcite surfaces. Nanoparticle concentration and brine salinity had a significant effect on the wettability alteration efficiency, and an optimum salinity was identified, analogous to that one found for surfactant formulations. Mechanistically, most nanoparticles irreversibly adhered to the oil-wet calcite surface (as substantiated by SEM-EDS and AFM measurements). We conclude that such nanofluid formulations can be very effective as enhanced hydrocarbon recovery agents and can potentially be used for improving the efficiency of CO2 geo-storage.

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Receding and advancing (CO 2 + brine + quartz) contact angles as a function of pressure, temperature, surface roughness, salt type and salinity

Al-Yaseri

Lebedev

Barifcani

et al. 2016

The Journal of Chemical Thermodynamics

206

170

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Impact of pressure and temperature on CO 2 –brine–mica contact angles and CO 2 –brine interfacial tension: Implications for carbon geo-sequestration

Arif

Al-Yaseri

Barifcani

et al. 2016

Journal of Colloid and Interface Science

237

124

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Impact of reservoir wettability and heterogeneity on CO 2 -plume migration and trapping capacity

Al‐Khdheeawi

Vialle

Barifcani

et al. 2017

International Journal of Greenhouse Gas Control

198

120

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Residual trapping of supercritical CO2 in oil-wet sandstone

Rahman

Lebedev

Barifcani

et al. 2016

Journal of Colloid and Interface Science

159

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Residual trapping, a key CO2 geo-storage mechanism during the first decades of a sequestration project, immobilizes micrometre sized CO2 bubbles in the pore network of the rock. This mechanism has been proven to work in clean sandstones and carbonates; however, this mechanism has not been proven for the economically most important storage sites into which CO2 will be initially injected at industrial scale, namely oil reservoirs. The key difference is that oil reservoirs are typically oil-wet or intermediate-wet, and it is clear that associated pore-scale capillary forces are different. And this difference in capillary forces clearly reduces the capillary trapping capacity (residual trapping) as we demonstrate here. For an oil-wet rock (water contact angle θ=130°) residual CO2 saturation SCO2,r (≈8%) was approximately halved when compared to a strongly water-wet rock (θ=0°; SCO2,r≈15%). Consequently, residual trapping is less efficient in oil-wet reservoirs.

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Ahmed Barifcani

Wettability alteration of oil-wet carbonate by silica nanofluid

Receding and advancing (CO 2 + brine + quartz) contact angles as a function of pressure, temperature, surface roughness, salt type and salinity

Impact of pressure and temperature on CO 2 –brine–mica contact angles and CO 2 –brine interfacial tension: Implications for carbon geo-sequestration

Impact of reservoir wettability and heterogeneity on CO 2 -plume migration and trapping capacity

Residual trapping of supercritical CO2 in oil-wet sandstone

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