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In situ pore-scale analysis of oil recovery during three-phase near-miscible CO2 injection in a water-wet carbonate rock

•Oil and water layers were not seen at near-miscible gas injection conditions.•Oil flows in centres of large pores rather than layers at near-miscible conditions.•Gas directly contacts water in the pore space at near-miscible conditions.•Microscopic displacement efficiency is highly improved at near...

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Published in:Advances in water resources 2019-12, Vol.134, p.103432, Article 103432
Main Authors: Alhosani, Abdulla, Scanziani, Alessio, Lin, Qingyang, Pan, Ziqing, Bijeljic, Branko, Blunt, Martin J.
Format: Article
Language:English
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Summary:•Oil and water layers were not seen at near-miscible gas injection conditions.•Oil flows in centres of large pores rather than layers at near-miscible conditions.•Gas directly contacts water in the pore space at near-miscible conditions.•Microscopic displacement efficiency is highly improved at near-miscible conditions.•Gas occupies the biggest pores, while oil and water occupy pores of varying sizes. We study in situ three-phase near-miscible CO2 injection in a water-wet carbonate rock at elevated temperature and pressure using X-ray microtomography. We examine the recovery mechanisms, presence or absence of oil layers, pore occupancy and interfacial areas during a secondary gas injection process. In contrast to an equivalent immiscible system, we did not observe layers of oil sandwiched between gas in the centre of the pore space and water in the corners. At near-miscible conditions, the measured contact angle between oil and gas was approximately 73°, indicating only weak oil wettability in the presence of gas. Oil flows in the centres of large pores, rather than in layers for immiscible injection, when displaced by gas. This allows for a rapid production of oil since it is no longer confined to movement in thin layers. A significant recovery factor of 80% was obtained and the residual oil saturation existed as disconnected blobs in the corners of the pore space. At equilibrium, gas occupied the biggest pores, while oil and water occupied pores of varying sizes (small, medium and large). Again, this was different from an immiscible system, where water occupied only the smallest pores. We suggest that a double displacement mechanism, where gas displaces water that displaces oil is responsible for shuffling water into larger pores than that seen after initial oil injection. This is only possible since, in the absence of oil layers, gas can contact water directly. The gas-oil and oil-water interfacial areas are lower than in the immiscible case, since there are no oil layers and even water layers in the macro-pore space become disconnected; in contrast, there is a larger direct contact of oil to the solid. These results could serve as benchmarks for developing near-miscible pore-scale modelling tools.
ISSN:0309-1708
1872-9657
DOI:10.1016/j.advwatres.2019.103432