Observation of Cement/Sandstone Interface after Reaction with Supercritical CO&lt;sub&gt;2 &lt;/sub&gt;Using SEM-EDS,  &amp;mu;-XRD, and  &amp;mu;-Raman Spectroscopy

Nakano, Kazuhiko; Mito, Saeko; Xue, Ziqiu; Ohbuchi, Atsushi

doi:10.1380/ejssnt.2016.198

Cited by 6 publications

(7 citation statements)

References 10 publications

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“…For these specimens, cement and steel integrity in the interface were preserved, meaning that the wellbore integrity is assured. Similar results were found from field (Carey et al, 2007;Duguid et al, 2014) and laboratory scale experiments (Mito et al, 2015;Nakano et al, 2016;Ren et al, 2016) indicating that perfectly bonded cement-casing interfaces may efficiently protect the casing against CO 2 induced degradation and act as a barrier to prevent CO 2 leakage from the geological formation (Beck et al, 2016;Carroll et al, 2016). However, other studies indicate that the cement-casing interface may lose its integrity over time in aggressive environments (Lorek et al, 2016;Ren et al, 2016) whereas field data show that interfacial defects are present to some extent of all wells evaluated (Carey et al, 2007;Duguid et al, 2014;Hawkes and Gardner, 2013).…”

Section: Cement-casing System: Showing No Interfacial Defectsupporting

confidence: 70%

“…Studies of cement carbonation (Bihua et al, 2018;Koukouzas et al, 2017) and steel casing corrosion (Nešić, 2007) are numerous. However, the evaluation of the cement-casing interface integrity is significantly limited (Asahara et al, 2013;Carey et al, 2010Carey et al, , 2009Mito et al, 2015;Nakano et al, 2016Nakano et al, , 2014Ren et al, 2016;Wolterbeek et al, 2016Wolterbeek et al, , 2013Wolterbeek and Raoof, 2018). Among them, only three works simulate interface degradation in the presence of wellbore defects (microannuli) and CO 2 -rich fluids in dynamic (Carey et al, 2010(Carey et al, , 2009 or static (Wolterbeek et al, 2013) systems, considering the simultaneous occurrence of cement carbonation and steel corrosion.…”

Section: Introductionmentioning

confidence: 99%

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Wellbore integrity in a saline aquifer: Experimental steel-cement interface degradation under supercritical CO2 conditions representative of Brazil’s Parana basin

Vecchia

Santos

Schütz

et al. 2020

International Journal of Greenhouse Gas Control

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From our work, significant progress has been made in understanding the degradation of cement-casing systems. The CO 2 degradation process was evaluated in specimens with a large interfacial defect, such as large annular spaces, voids and/or channels, which may be the result of a poor cementing job. From the experiments showing no interfacial defect, no signs of degradation were observed, while from experiments showing interfacial defect, both the cement and steel undergo significant degradation. In the well casing, the CO 2 -rich brine affects the steel phase, leaching Fe 2+ ions into solution and promoting FeCO 3 precipitation on the material surface, while on the cement sheath, two processes are occurring: (i) the portlandite dissolution and (ii) the cement carbonation process. Then, iron (Fe 2+ ) starts to migrate into the cement structure, compromising the material's self-healing and pore-blocking features, while calcium (Ca 2+ ) starts to compose the corrosion film from the formation of mixed carbonates (Fe x Ca y CO 3 ) so reducing the corrosion layer's protection. Finally, both ions (Ca 2+ and Fe 2+ ) become so abundant in the material vicinity that they may form calcium carbonate (CaCO 3 ) on the corrosion layer and iron carbonate (FeCO 3 ) in the cement matrix. Thus, from our results, the degradation mechanisms of the cement-casing system in CO 2 -rich brine was revised.

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Section: Cement-casing System: Showing No Interfacial Defectsupporting

confidence: 70%

Section: Introductionmentioning

confidence: 99%

Wellbore integrity in a saline aquifer: Experimental steel-cement interface degradation under supercritical CO2 conditions representative of Brazil’s Parana basin

Vecchia

Santos

Schütz

et al. 2020

International Journal of Greenhouse Gas Control

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“…However, the XRD patterns show sharp calcite reflections, confirming the effective formation of calcite. 20,24−26,48,51,59 Further, a comparison of the XRD patterns for the CaCO 3 particles acquired using GO and/or rGO reveals that the XRD peaks for the hydrated cement mixed with GO and/or rGO are sharper than those of the hydrated cement without any additives.…”

Section: Resultsmentioning

confidence: 96%

“…14−17 In addition, multiple studies have been committed to investigate the carbonation effects on the reinforced cement durability, 2,18−26 and environmental factors such as temperature, relative humidity, and partial pressure of carbon dioxide have been found to have enormous effects on the carbonation of hydrated cement. 19,20,24−26 Indeed, the carbonation of hydrated cement implies an intricate effect on the microstructure; 27−30 mild CO 2 exposure enhances the compressive strength, while extended exposure might negatively influence the mechanical properties. More importantly, Pavlik 21,22 demonstrated that the reaction of the hydrated cement with atmospheric CO 2 is generally a slow process and is highly dependent on some environmental factors such as the concentration of atmospheric CO 2 , temperature, and permeability of the material.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, the increased attention on civil infrastructure enhancement has motivated research on the possible modification of cement-based materials to fulfill the growing requirements for sustainability in the construction field. , Modification is performed by some selective additives and adjusting the cement composition. Several attempts have been done to enhance the hardness, durability, and tensile properties of the cement by utilizing different kinds of reinforcing materials, from carbon fibers, steel fibers, and polymer fibers − to nanomaterials, , such as carbon nanotubes, graphene derivatives, and nanosilica. − In addition, multiple studies have been committed to investigate the carbonation effects on the reinforced cement durability, ,− and environmental factors such as temperature, relative humidity, and partial pressure of carbon dioxide have been found to have enormous effects on the carbonation of hydrated cement. ,,− Indeed, the carbonation of hydrated cement implies an intricate effect on the microstructure; − mild CO 2 exposure enhances the compressive strength, while extended exposure might negatively influence the mechanical properties. More importantly, Pavlik , demonstrated that the reaction of the hydrated cement with atmospheric CO 2 is generally a slow process and is highly dependent on some environmental factors such as the concentration of atmospheric CO 2 , temperature, and permeability of the material.…”

Section: Introductionmentioning

confidence: 99%

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Elucidation of Calcite Structure of Calcium Carbonate Formation Based on Hydrated Cement Mixed with Graphene Oxide and Reduced Graphene Oxide

Yaseen

Yiseen

Li³

2019

ACS Omega

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In this study, the carbonation of Portland cement by direct chemical interaction with graphene oxide (GO) and reduced graphene oxide (rGO) at 7 and 28 days was examined. During the carbonation reaction, the calcium-bearing phases (calcium hydroxide, calcium silicate hydrate, and ettringite) formed calcium carbonate polymorphs, along with amorphous silica gel, gypsum, and alumina gel. These reaction products were examined using XRD (X-ray diffraction), XPS (energy-dispersive spectrometry), and FTIR (Fourier transform infrared). XRD patterns showed that the intensities of the calcium hydroxide and calcium carbonate peaks in the hydrated cement mixed with GO and/or rGO are higher than the corresponding peaks in the hydrated cement without any additives. The morphology of the reaction products was also characterized by SEM (scanning electron microscopy) measurements, which showed that a needle-like phase of calcium carbonate develops on the hydrated cement. The obtained microstructure parameters enabled the development of a more precise carbonation model.

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Self-sealing of Wellbore Cement under the CO2 Batch Experiment Using Well Composite Sample

2017

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Observation of Cement/Sandstone Interface after Reaction with Supercritical CO<sub>2 </sub>Using SEM-EDS, μ-XRD, and μ-Raman Spectroscopy

Cited by 6 publications

References 10 publications

Wellbore integrity in a saline aquifer: Experimental steel-cement interface degradation under supercritical CO2 conditions representative of Brazil’s Parana basin

Wellbore integrity in a saline aquifer: Experimental steel-cement interface degradation under supercritical CO2 conditions representative of Brazil’s Parana basin

Elucidation of Calcite Structure of Calcium Carbonate Formation Based on Hydrated Cement Mixed with Graphene Oxide and Reduced Graphene Oxide

Self-sealing of Wellbore Cement under the CO2 Batch Experiment Using Well Composite Sample

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