Real Time 3D Observations of Portland Cement Carbonation at CO2 Storage Conditions

Real Time 3D Observations of Portland Cement Carbonation at CO2 Storage Conditions

Depleted oil reservoirs are considered a viable solution to the global challenge of CO2 storage. A key concern is whether the wells can be suitably sealed with cement to hinder the escape of CO2. Under reservoir conditions, CO2 is in its supercritical state, and the high pressures and temperatures i...

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Bibliographic Details
Published in:Environmental science & technology Vol. 54; no. 13; pp. 8323 - 8332
Main Authors: Chavez Panduro, Elvia A, Cordonnier, Benoît, Gawel, Kamila, Børve, Ingrid, Iyer, Jaisree, Carroll, Susan A, Michels, Leander, Rogowska, Melania, McBeck, Jessica Ann, Sørensen, Henning Osholm, Walsh, Stuart D. C, Renard, François, Gibaud, Alain, Torsæter, Malin, Breiby, Dag W
Format: Journal Article
Language:English
Published: Easton American Chemical Society 07-07-2020
ACS Publications
American Chemical Society (ACS)
Subjects:
Calcium
Calcium carbonate
Carbon dioxide
Carbon sequestration
Carbonation
Cement
Chemical precipitation
Computed tomography
Deformation
Dissolution
Energy and Climate
GEOSCIENCES
Image resolution
Layers
Oil reservoirs
Physics
Portland cement
Portland cements
Precipitation
Real time
Reservoir storage
Reservoirs
Silica
Storage conditions
TOMOGRAPHY
H WELL CEMENT
PRECIPITATION
TEMPERATURE
REACTIVE TRANSPORT
INTEGRITY
MICROTOMOGRAPHY
STRAIN LOCALIZATION
DIGITAL VOLUME CORRELATION
MORPHOLOGY
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Summary:Depleted oil reservoirs are considered a viable solution to the global challenge of CO2 storage. A key concern is whether the wells can be suitably sealed with cement to hinder the escape of CO2. Under reservoir conditions, CO2 is in its supercritical state, and the high pressures and temperatures involved make real-time microscopic observations of cement degradation experimentally challenging. Here, we present an in situ 3D dynamic X-ray micro computed tomography (μ-CT) study of well cement carbonation at realistic reservoir stress, pore-pressure, and temperature conditions. The high-resolution time-lapse 3D images allow monitoring the progress of reaction fronts in Portland cement, including density changes, sample deformation, and mineral precipitation and dissolution. By switching between flow and nonflow conditions of CO2-saturated water through cement, we were able to delineate regimes dominated by calcium carbonate precipitation and dissolution. For the first time, we demonstrate experimentally the impact of the flow history on CO2 leakage risk for cement plugging. In-situ μ-CT experiments combined with geochemical modeling provide unique insight into the interactions between CO2 and cement, potentially helping in assessing the risks of CO2 storage in geological reservoirs.
Bibliography:NFR/275182
AC52-07NA27344
LLNL-JRNL-798691
USDOE National Nuclear Security Administration (NNSA)
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.0c00578