Characterization of flow parameters and evidence of pore clogging during limestone dissolution experiments

Rock dissolution induces changes in texture (porosity, pore‐size distribution, or tortuosity) which modify multiphase flow and transport properties (permeability, diffusion coefficient, retention curve). Limestone dissolution will occur during CO2 storage or acid injection for well stimulation. Ther...

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Bibliographic Details
Published in:Water resources research 2014-08, Vol.50 (8), p.6305-6321
Main Authors: Luquot, L., Roetting, T. S., Carrera, J.
Format: Article
Language:English
Subjects:
ATM PCO
Calcite
Calç
Carbon dioxide
CO2 SEQUESTRATION
CO2 storage
CO2-INDUCED DISSOLUTION
Continental interfaces, environment
Diffusion coefficient
Dissolution
Earth Sciences
Enginyeria civil
Experiments
Geologia
Hidrologia subterrània
Hydrology
Injection
Inlets
laboratory experiments
Lime
Limestone
Multiphase flow
multiphase flow parameters
Outlets
PERMEABILITY
Pores
Porosity
POROUS-MEDIA
REACTIVE FLUID
Rocks
Sciences of the Universe
Stone
Storage capacity
Trapping
WORMHOLE FORMATION
Àrees temàtiques de la UPC
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Summary:Rock dissolution induces changes in texture (porosity, pore‐size distribution, or tortuosity) which modify multiphase flow and transport properties (permeability, diffusion coefficient, retention curve). Limestone dissolution will occur during CO2 storage or acid injection for well stimulation. Therefore, characterizing those changes is essential for understanding flow and transport during and after the CO2 injection because they can affect the storage capacity, injectivity, and trapping mechanisms. Yet, few published studies evaluate the changes of hydrodynamic properties due to fluid‐rock interactions. We report seven dissolution experiments performed on four limestone samples by injecting water with pH ranging from 3.5 to 5.0. Sample porosity, diffusion coefficient, and pore‐size distribution were measured before and after each rock attack, which was repeated twice on three of the samples. Permeability was monitored continuously and chemical samples were taken to evaluate calcite dissolution. We find that overall porosity increases over time as expected. But the increase is nonuniform along the sample. At the samples inlets, large pores increase significantly while small pores remain unchanged, which is consistent with wormhole initiation. However, the size of largest pores is reduced at the outlet, which we attribute to clogging by particles dragged from the inlet. As a result, the overall permeability is reduced. Particle dragging is unlikely during supercritical CO2 storage because head gradients are small, but may be expected in the case of dissolved CO2 injection or during well stimulation by acid injection. Our results imply that dissolution is highly localized, which will result in a significant increase in capillary trapping. Key Points A new methodology to evaluate flow and transport parameters Clogging phenomenon observed during calcite dissolution Permeability‐porosity/diffusion coefficient relationships are negative
ISSN:0043-1397
1944-7973
DOI:10.1002/2013WR015193