Pore-scale contact angle measurements at reservoir conditions using X-ray microtomography

Contact angle is a principal control of the flow of multiple fluid phases through porous media; however its measurement on other than flat surfaces remains a challenge. A new method is presented for the mea- surement of the contact angle between immiscible fluids at the pore scale at reservoir conditions (10 MPa and 50 C) inside a quarry limestone through the use of X-ray microtomography. It is applied to a super- critical CO2-brine-carbonate system by resampling the micro-CT data onto planes orthogonal to the con- tact lines, allowing for vectors to be traced along the grain surface and the CO2-brine interface. A distri- bution of contact angles ranging from 35 to 55 is observed, indicating that the CO2-brine-carbonate system is weakly water-wet. This range of contact angles can be understood as the result of contact angle hysteresis and surface heterogeneity on a range of length scales. Surface heterogeneity is examined by comparison of micro-CT results with optical thin sections and SEM images. 2014 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-SA license

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