Pore-scale 4D imaging demonstrates that hydrocarbon swelling and mobilisation compete to control the non-monotonic dissolution rate of carbonate by CO2-saturated brine via changes in advective access.
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Pore-resolved CFD diagnoses surface-access limitations in catalytic monoliths, showing that topology can reduce required pumping power by up to an order of magnitude for the same production rate.
citing papers explorer
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Time-Resolved Pore-Scale Imaging of Multiphase Dissolution during CO2-Saturated Brine Injection into a Carbonate: Competition between Hydrocarbon Mobilisation and Swelling
Pore-scale 4D imaging demonstrates that hydrocarbon swelling and mobilisation compete to control the non-monotonic dissolution rate of carbonate by CO2-saturated brine via changes in advective access.
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Surface-access limitation in catalytic porous monoliths: Performance diagnosis using pore-resolved CFD
Pore-resolved CFD diagnoses surface-access limitations in catalytic monoliths, showing that topology can reduce required pumping power by up to an order of magnitude for the same production rate.