Closing of Micro-cavities in Well Cement upon Exposure to CO2 Brine

E. A.Chavez Panduro; M. Torsæter; K. Gawel; R. Bjørge; A. Gibaud; Y. Yang; H. O. Sørensen; P. Frykman; C. Kjøller; D. W. Breiby

doi:10.1016/j.egypro.2017.03.1665

Closing of Micro-cavities in Well Cement upon Exposure to CO₂ Brine

E. A.Chavez Panduro, M. Torsæter^*, K. Gawel, R. Bjørge, A. Gibaud, Y. Yang, H. O. Sørensen, P. Frykman, C. Kjøller, D. W. Breiby

^*Corresponding author af dette arbejde

Kemisk Institut

8 Citationer (Scopus)

52 Downloads (Pure)

Abstract

Long-lasting cement plugging of wells is crucial for successful CO₂ storage in underground reservoirs. It requires a profoundly improved understanding of the behavior of fractured cement under realistic subsurface conditions including elevated temperature, high pressure and the presence of CO₂ saturated brine. Here we report computed X-ray tomography studies on the effects of CO₂ on cement. More specifically, we have exposed cured Portland G cement samples with pre-made microchannels mimicking fractures to CO₂ saturated brine at elevated pressure (100 bars) and room temperature. The microchannels were observed to get filled with calcite (CaCO₃) during the CO₂ exposure. The extent of this self-healing was dependent on the diameter of the leakage path, with narrower channels more readily getting clogged. Chemical simulations taking into account the cement composition, CO₂ availability, pH, pressure and temperature gave results consistent with our conceptual understanding of how the differences in dissolution/precipitation profiles in the cement may result from the availability of CO₂. In particular, the modelling provides an explanation why calcite precipitates preferentially in the channels rather than on the external cement sample surfaces. We conclude that the localized precipitation can be ascribed to higher pH inside the cavities compared to near the external surfaces, owing to long diffusion distances giving a locally limited CO₂ supply within the voids.

Originalsprog	Engelsk
Tidsskrift	Energy Procedia
Vol/bind	114
Sider (fra-til)	5100-5108
Antal sider	9
ISSN	1876-6102
DOI	https://doi.org/10.1016/j.egypro.2017.03.1665
Status	Udgivet - 2017
Begivenhed	13th International Conference on Greenhouse Gas Control Technologies, GHGT 2016 - Lausanne, Schweiz Varighed: 14 nov. 2016 → 18 nov. 2016

Konference

Konference	13th International Conference on Greenhouse Gas Control Technologies, GHGT 2016
Land/Område	Schweiz
By	Lausanne
Periode	14/11/2016 → 18/11/2016

Adgang til dokumentet

10.1016/j.egypro.2017.03.1665Licens: CC BY

Closing of Micro-cavities in Well Cement upon Exposure to CO2 BrineForlagets udgivne version, 3,43 MBLicens: CC BY

Citationsformater

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title = "Closing of Micro-cavities in Well Cement upon Exposure to CO2 Brine",

abstract = "Long-lasting cement plugging of wells is crucial for successful CO2 storage in underground reservoirs. It requires a profoundly improved understanding of the behavior of fractured cement under realistic subsurface conditions including elevated temperature, high pressure and the presence of CO2 saturated brine. Here we report computed X-ray tomography studies on the effects of CO2 on cement. More specifically, we have exposed cured Portland G cement samples with pre-made microchannels mimicking fractures to CO2 saturated brine at elevated pressure (100 bars) and room temperature. The microchannels were observed to get filled with calcite (CaCO3) during the CO2 exposure. The extent of this self-healing was dependent on the diameter of the leakage path, with narrower channels more readily getting clogged. Chemical simulations taking into account the cement composition, CO2 availability, pH, pressure and temperature gave results consistent with our conceptual understanding of how the differences in dissolution/precipitation profiles in the cement may result from the availability of CO2. In particular, the modelling provides an explanation why calcite precipitates preferentially in the channels rather than on the external cement sample surfaces. We conclude that the localized precipitation can be ascribed to higher pH inside the cavities compared to near the external surfaces, owing to long diffusion distances giving a locally limited CO2 supply within the voids.",

keywords = "cement, CO, microcomputed tomography, self-healing",

author = "Panduro, {E. A.Chavez} and M. Tors{\ae}ter and K. Gawel and R. Bj{\o}rge and A. Gibaud and Y. Yang and S{\o}rensen, {H. O.} and P. Frykman and C. Kj{\o}ller and Breiby, {D. W.}",

year = "2017",

doi = "10.1016/j.egypro.2017.03.1665",

language = "English",

volume = "114",

pages = "5100--5108",

journal = "Energy Procedia",

issn = "1876-6102",

publisher = "Elsevier",

note = "13th International Conference on Greenhouse Gas Control Technologies, GHGT 2016 ; Conference date: 14-11-2016 Through 18-11-2016",

}

TY - GEN

T1 - Closing of Micro-cavities in Well Cement upon Exposure to CO2 Brine

AU - Panduro, E. A.Chavez

AU - Torsæter, M.

AU - Gawel, K.

AU - Bjørge, R.

AU - Gibaud, A.

AU - Yang, Y.

AU - Sørensen, H. O.

AU - Frykman, P.

AU - Kjøller, C.

AU - Breiby, D. W.

PY - 2017

Y1 - 2017

N2 - Long-lasting cement plugging of wells is crucial for successful CO2 storage in underground reservoirs. It requires a profoundly improved understanding of the behavior of fractured cement under realistic subsurface conditions including elevated temperature, high pressure and the presence of CO2 saturated brine. Here we report computed X-ray tomography studies on the effects of CO2 on cement. More specifically, we have exposed cured Portland G cement samples with pre-made microchannels mimicking fractures to CO2 saturated brine at elevated pressure (100 bars) and room temperature. The microchannels were observed to get filled with calcite (CaCO3) during the CO2 exposure. The extent of this self-healing was dependent on the diameter of the leakage path, with narrower channels more readily getting clogged. Chemical simulations taking into account the cement composition, CO2 availability, pH, pressure and temperature gave results consistent with our conceptual understanding of how the differences in dissolution/precipitation profiles in the cement may result from the availability of CO2. In particular, the modelling provides an explanation why calcite precipitates preferentially in the channels rather than on the external cement sample surfaces. We conclude that the localized precipitation can be ascribed to higher pH inside the cavities compared to near the external surfaces, owing to long diffusion distances giving a locally limited CO2 supply within the voids.

AB - Long-lasting cement plugging of wells is crucial for successful CO2 storage in underground reservoirs. It requires a profoundly improved understanding of the behavior of fractured cement under realistic subsurface conditions including elevated temperature, high pressure and the presence of CO2 saturated brine. Here we report computed X-ray tomography studies on the effects of CO2 on cement. More specifically, we have exposed cured Portland G cement samples with pre-made microchannels mimicking fractures to CO2 saturated brine at elevated pressure (100 bars) and room temperature. The microchannels were observed to get filled with calcite (CaCO3) during the CO2 exposure. The extent of this self-healing was dependent on the diameter of the leakage path, with narrower channels more readily getting clogged. Chemical simulations taking into account the cement composition, CO2 availability, pH, pressure and temperature gave results consistent with our conceptual understanding of how the differences in dissolution/precipitation profiles in the cement may result from the availability of CO2. In particular, the modelling provides an explanation why calcite precipitates preferentially in the channels rather than on the external cement sample surfaces. We conclude that the localized precipitation can be ascribed to higher pH inside the cavities compared to near the external surfaces, owing to long diffusion distances giving a locally limited CO2 supply within the voids.

KW - cement

KW - CO

KW - microcomputed tomography

KW - self-healing

U2 - 10.1016/j.egypro.2017.03.1665

DO - 10.1016/j.egypro.2017.03.1665

M3 - Conference article

AN - SCOPUS:85027585423

SN - 1876-6102

VL - 114

SP - 5100

EP - 5108

JO - Energy Procedia

JF - Energy Procedia

T2 - 13th International Conference on Greenhouse Gas Control Technologies, GHGT 2016

Y2 - 14 November 2016 through 18 November 2016

ER -