https://orcid.org/0000-0002-5167-6014
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ABSTRACT
In the context of geological CO2 sequestration projects, CO2/water/rock wettability directly affects the capacities of residual and structural trapping mechanisms. Therefore, presenting an accurate model that can simulate the wettability behavior of CO2/water/rock under different environmental conditions is necessary. In this study, a new model based on adaptive neuro-fuzzy interference system (ANFIS) was developed for estimation of CO2/water/quartz contact angle as a function of influencing parameters, such as pressure, temperature, salinity, and salt type. Results of the proposed model were compared to the actual data and it was found that the presented model has immense potential with high correlation coefficient (R2) of 0.991 and average absolute relative error (AARE) of 2.010 for predicting the CO2/water/quartz contact angle. Finally, a sensitivity analysis was performed on the influencing factors. Results of this analysis demonstrated that salinity and pressure have the highest impact on the wettability of CO2/water/quartz.
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Notes on contributors
Amin Daryasafar
Amin Daryasafar received his academic degrees from Petroleum University of Technology (PUT) and has work experience as petroleum reservoir engineer at National Iranian South Oil Company (NISOC). He has worked on different research areas of petroleum engineering including numerical modeling and simulation of conventional and unconventional reservoirs, using nanoparticles for scale formation inhibition, modeling heat transfer in fractured reservoirs, modeling reservoir fluids properties, and enhanced oil recovery (EOR) techniques such as microbial enhanced oil recovery (MEOR), surfactants, polymers, nanofluids flooding, etc.
Khalil Shahbazi
Khalil Shahbazi is an Associate Professor of Petroleum Engineering at the Petroleum University of Technology. He received his PhD in Petroleum Engineering from University of Calgary. His research interests including Conventional and Underbalanced Drilling, Drilling Fluids and Rheology of Non-Newtonian Fluids, Hydraulic Fracturing Modeling, Applications of Finite Difference in Wellbore and Near-Wellbore Flow, Multi-Phase Flow in Wellbores and Fractures.