Carbonation of silica cement at high-temperature well conditions

•Silica-amended well cement and neat well cement were exposed to CO2-saturated brine at 120°C/280 bar and 90°C/280 bar, respectively.•Microstructural changes were studied using μ-CT, XRD and SEM.•In the silica cement, the carbonated region consisted of two distinct layers with a rough interface regi...

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Bibliographic Details
Published in:International journal of greenhouse gas control 2019-03, Vol.82, p.261-268
Main Authors: Bjørge, Ruben, Gawel, Kamila, Chavez Panduro, Elvia A., Torsæter, Malin
Format: Article
Language:English
Subjects:
CCS
Cement
CO2 exposure
CO2 storage
Silica
Well integrity
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Summary:•Silica-amended well cement and neat well cement were exposed to CO2-saturated brine at 120°C/280 bar and 90°C/280 bar, respectively.•Microstructural changes were studied using μ-CT, XRD and SEM.•In the silica cement, the carbonated region consisted of two distinct layers with a rough interface region containing wormhole-like features. Cements for well environments with temperatures above 110 °C are typically designed with silica additions. This is the case for many of the wells in the North Sea, which is a region promising for large-scale geological storage of CO2 from European sources. Wells are probable leakage paths in carbon capture and storage (CCS) projects, and it is therefore important to understand how CO2 interacts with cement under downhole conditions. In this study, microstructural changes associated with carbonation of cement with and without silica were followed using micro-computed tomography, X-ray diffraction and scanning electron microscopy. The rims of the cement cores exposed to CO2-saturated brine consisted of a carbonated region and a bicarbonated region. In the silica cement sample, the carbonated region consisted of two distinct layers with a rough interface region containing wormhole-like features. The formation of these two layers in the silica cement is proposed to be due to calcium carbonate dissolution and re-precipitation during exposure to CO2-saturated brine. The results illustrate the importance of the effect of additives for offshore CO2-storage well integrity.
ISSN:1750-5836
1878-0148
DOI:10.1016/j.ijggc.2019.01.011