Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Carbonization of Class G well cement containing metakaolin under supercritical and saturated environments
Graphical abstract Display Omitted
Highlights Well cement alteration under relevant subsurface conditions at high pressures and temperatures. The presence of CaCO3 in well cement samples shows that a carbonization reaction has occurred. The more extensive carbonization was under the CO2 saturated solution than under supercritical CO2. Larger CO2 ingress was observed when cement slurries were mixed with MK.
Abstract A well-cement alteration in a CO2-rich environment can affect the well integrity, and, consequently, compromise the overall safety of an external ecosystem. The objective of this study was to evaluate the carbonization of Class G well cement and metakaolin modified Class G cement samples exposed to CO2 at 323 K and 15 MPa under supercritical state and in the saturated solution. Cement alternation was more rapid and extensive under a CO2 saturated solution than under supercritical CO2. Metakaolin amended Class G cement samples showed improved mechanical properties, while their carbonation resistance was impaired and reduced. X-ray Powder Diffraction confirmed that CaCO3 polymorphs were present in greater proportions in the metakaolin-modified samples and when exposed to a CO2-saturated salt solution. Moreover, samples containing metakaolin have a larger specific surface area, and, consequently, can absorb more CO2. The micrographs showed that the cement samples exposed to a CO2-rich environment have rough and porous surfaces containing CaCO3 polymorphic crystalline forms.
Carbonization of Class G well cement containing metakaolin under supercritical and saturated environments
Graphical abstract Display Omitted
Highlights Well cement alteration under relevant subsurface conditions at high pressures and temperatures. The presence of CaCO3 in well cement samples shows that a carbonization reaction has occurred. The more extensive carbonization was under the CO2 saturated solution than under supercritical CO2. Larger CO2 ingress was observed when cement slurries were mixed with MK.
Abstract A well-cement alteration in a CO2-rich environment can affect the well integrity, and, consequently, compromise the overall safety of an external ecosystem. The objective of this study was to evaluate the carbonization of Class G well cement and metakaolin modified Class G cement samples exposed to CO2 at 323 K and 15 MPa under supercritical state and in the saturated solution. Cement alternation was more rapid and extensive under a CO2 saturated solution than under supercritical CO2. Metakaolin amended Class G cement samples showed improved mechanical properties, while their carbonation resistance was impaired and reduced. X-ray Powder Diffraction confirmed that CaCO3 polymorphs were present in greater proportions in the metakaolin-modified samples and when exposed to a CO2-saturated salt solution. Moreover, samples containing metakaolin have a larger specific surface area, and, consequently, can absorb more CO2. The micrographs showed that the cement samples exposed to a CO2-rich environment have rough and porous surfaces containing CaCO3 polymorphic crystalline forms.
Carbonization of Class G well cement containing metakaolin under supercritical and saturated environments
Kravanja, Gregor (Autor:in) / Knez, Željko (Autor:in)
12.03.2023
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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