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Public Documents
1
Time-Lapse Imaging of Reactive Mixing Inducing Carbonate Mineralization in Basalt Cor...
Paiman Shafabakhsh
and 8 more
November 04, 2024
Mineral precipitation in geological formations occurs when reactive fluids of varying compositions mix, altering the porous microstructure of the rock. Basalt rocks are of particular interest for long-term CO2 storage due to their potential to rapidly mineralize CO2 into stable carbonate minerals. We investigated reactive fluid mixing and subsequent carbonate mineralization in porous basalt using time-lapse three-dimensional neutron and X-ray imaging. Two flow-through experiments with different injection rates were performed on basalt cores, where co-injected CaCl2 and Na2CO3 solutions were mixed within the porous network, leading to calcium carbonate precipitation. Time-lapse neutron imaging distinguished the two injected fluids and tracked their mixing. X-ray imaging was used to separate the solid matrix from the pore space to enable fluid analysis in the neutron images. A first experiment with a high flow rate induced a steady transverse mixing pattern, captured by a decay of the concentration variance through the sample, as measured by neutron imaging. A second experiment at a lower flow rate promoted more temporal fluctuations in the fluid distribution due to the multiphase flow of water and air in the rock. The analysis of neutron images showed a significant mixing of reactive fluids driven by these temporal fluctuations. Furthermore, a higher-resolution, synchrotron X-ray image of one of the sample rocks acquired after the experiment showed the formation of additional calcite resulting from long-term diffusive mixing. The results highlight the great potential and challenges of neutron and X-ray imaging in characterizing pore-scale mixing and precipitation in rocks.