Fracture healing and transport properties of wellbore cement in the presence of supercritical CO2

This paper investigates the process and rate of carbonation reaction of Class A wellbore cement exposed to CO2-saturated solution at confined conditions similar to those employed in geological storage of CO2. The main goal was to investigate whether reaction improves or degrades the sealing/healing...

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Bibliographic Details
Published in:Chemical geology 2011-02, Vol.281 (3-4), p.195-210
Main Authors: Liteanu, E, Spiers, C J
Format: Article
Language:English
Subjects:
Carbon dioxide
Carbonation
Cements
Confining
Fracture mechanics
Healing
Marine
Permeability
Sealing
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Summary:This paper investigates the process and rate of carbonation reaction of Class A wellbore cement exposed to CO2-saturated solution at confined conditions similar to those employed in geological storage of CO2. The main goal was to investigate whether reaction improves or degrades the sealing/healing capacity of fractured Type A cement plugs. Batch reaction experiments were performed for up to three months, on both intact and fractured Class A Portland cement cylinders, at a constant confining pressure of 30MPa, a temperature of 80 degree C and a CO2 pressure of 10MPa. The experiments were carried out on water-saturated samples, exposing them to the supercritical CO2 at one end. All samples were jacketed in sleeves to seal them from the high pressure confining medium. The results indicate that cement carbonation front advanced in time, leading to a densification of the material. Extrapolation of the reaction rates to 1-year period indicates a carbonation depth of about 1.38mm, and about 7.56mm after 30years of exposure to CO2-saturated solution. Thermogravimetric analyses, Scanning Electron Microscopy observations and permeability measurements indicate that carbonation of wellbore cement leads to a decrease of the porosity of the material on the reaction front and moreover, has the potential for healing pre-existent fractures and for improving the sealing properties of good-quality cement samples in time, at reservoir conditions.
ISSN:0009-2541
DOI:10.1016/j.chemgeo.2010.12.008