Identifying geochemical reactions on wellbore cement/caprock interface under sequestration conditions

Labus, Małgorzata; Wertz, Frédéric

doi:10.1007/s12665-017-6771-x

Cited by 7 publications

(1 citation statement)

References 32 publications

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“…This reaction changes pH of the acidic brine and makes it more acidic. The first and fast reaction which occurs is the dissolution of calcite whereas calcite present at the cement-formation interface has almost disappeared and a microannulus is created [42]. It should be noted that at downhole conditions, the dissolution process of calcite may be slower as the amount of acidified water is less compared to the laboratory case at which this study was performed.…”

Section: Role Of Materials Degradation and Tectonic Loads On Durabilitmentioning

confidence: 90%

Specification for Permanent Plugging Materials

Khalifeh¹,

Saasen²

2020

Ocean Engineering &Amp; Oceanography

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Section: Role Of Materials Degradation and Tectonic Loads On Durabilitmentioning

confidence: 90%

Specification for Permanent Plugging Materials

Khalifeh¹,

Saasen²

2020

Ocean Engineering &Amp; Oceanography

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Geochemical modeling of CO2 injection and gypsum precipitation at the Ketzin CO2 storage site

et al. 2022

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Gypsum crystals are found at the well perforation of observation well Ktzi 202 of the test site for CO2 storage at Ketzin, Germany. XRD analysis confirms pure gypsum. Fluid samples before and after CO2 injection are analyzed. Geochemical modeling is conducted to identify the mechanisms that lead to gypsum formation. The modeling is carried out with PHREEQC and Pitzer database due to the high salinity of up to 5 mol per kg water. Due to their significantly higher reactivity compared to other minerals like silicates, calcite, dolomite, magnesite, gypsum, anhydrite, and halite are considered as primary mineral phases for matching the observed brine compositions in our simulations. Calcite, dolomite, and gypsum are close to saturation before and after CO2 injection. Dolomite shows the highest reactivity and mainly contributes to buffering the brine pH that initially decreased due to CO2 injection. The contribution of calcite to the pH-buffering is only minor. Gypsum and anhydrite are no geochemically active minerals before injection. After CO2 injection, gypsum precipitation may occur by two mechanisms: (i) dissociation of CO2 decreases activity of water and, therefore, increases the saturation of all minerals and (ii) dolomite dissolution due to pH-buffering releases Ca2+ ions into solution and shifts the mass action to gypsum. Gypsum precipitation decreases with increasing temperature but increases with increasing partial CO2 pressure. Our calculations show that calcium sulfate precipitation increases by a factor of 5 to a depth of 2000 m when Ketzin pressure and temperature are extrapolated. In general, gypsum precipitation constitutes a potential clogging hazard during CO2 storage and could negatively impact safe site operation. In the presented Ketzin example, this threat is only minor since the total amount of gypsum precipitation is relatively small.

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