Qualitative and quantitative changes in detrital reservoir rocks caused by CO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt;–brine–rock interactions during first injection phases (Utrillas sandstones, northern Spain)

Berrezueta, Edgar; Ordóñez-Casado, Berta; Quintana, Leonard R.

doi:10.5194/se-7-37-2016

Cited by 7 publications

(3 citation statements)

References 53 publications

(60 reference statements)

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“…However, the increase in pH correlates positively with the time of rock-brine interaction (Tables 6 and 7). The trends of the pH measurements correspond to those found in previous experimental works carried out in an autoclave [25,[37][38][39].…”

Section: Resultssupporting

confidence: 86%

“…for the final arrangement of the experimental device and run conditions. The autoclave (Figure 2c) [36,39] has two CO 2 cylinders (standard industrial CO 2 at 4.5 MPa) that are linked to the other elements of the system by steel connectors (diameter: 5 mm). The first CO 2 cylinder is directly connected with the chamber.…”

Section: Experimental Procedures (Autoclave)mentioning

confidence: 99%

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Mineral Carbonation of CO2 in Mafic Plutonic Rocks, II—Laboratory Experiments on Early-Phase Supercritical CO2‒Brine‒Rock Interactions

et al. 2020

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The potential for mineral carbonation of CO2 in plutonic mafic rocks is addressed through a set of laboratory experiments on cumulate gabbro and gabbro-diorite specimens from the Sines Massif (Portugal). The experiments were conducted in an autoclave, for a maximum of 64 days, using a CO2 supersaturated brine under pressure and temperature conditions similar to those expected around an injection well during early-phase CO2 injection. Multiple techniques for mineralogical and geochemical characterization were applied ante- and post-carbonation experiments. New mineralogical phases (smectite, halite and gypsum), roughness increase and material loss were observed after exposure to the CO2 supersaturated brine. The chemical analysis shows consistent changes in the brine and rock specimens: (i) increases in iron (Fe) and magnesium (Mg) in the aqueous phase and decreases in Fe2O3 and MgO in the specimens; (ii) a decrease in aqueous calcium (Ca) and an increase in CaO in the cumulate gabbro, whereas in the gabbro-diorite aqueous Ca increased and afterwards remained constant, whereas CaO decreased. The geochemical model using the CrunchFlow code was able to reproduce the experimental observations and simulate the chemical behavior for longer times. Overall, the study indicates that the early-stage CO2 injection conditions adopted induce mainly a dissolution phase with mineralogical/textural readjustments on the external area of the samples studied.

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Section: Resultssupporting

confidence: 86%

Section: Experimental Procedures (Autoclave)mentioning

confidence: 99%

Mineral Carbonation of CO2 in Mafic Plutonic Rocks, II—Laboratory Experiments on Early-Phase Supercritical CO2‒Brine‒Rock Interactions

et al. 2020

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“…The results of rock characterization provide valuable information for modelling and assessing fundamental reservoir properties, such as injectivity, storage capacity or reactive processes [4,[7][8][9][10][11]. As far as injectivity is concerned, the porosity and permeability of the reservoir rock and the chemical reactions in the CO 2 -brine-rock system (i.e., mineral dissolution/precipitation) are decisive [4,12].…”

Section: Introduction and Objectivesmentioning

confidence: 99%

Petrographic and Petrophysical Characterization of Detrital Reservoir Rocks for CO2 Geological Storage (Utrillas and Escucha Sandstones, Northern Spain)

Mateos-Redondo¹,

Kovács²,

Berrezueta

2018

Geosciences

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Abstract:The aim of this article is to provide a qualitative and quantitative description of Lower-Upper Cretaceous detrital rocks (Escucha and Utrillas sandstones) in order to explore their potential use as CO 2 reservoirs based on their petrographic and petrophysical characteristics. Optical microscopy (OpM) and scanning electron microscopy (SEM) aided by optical image analysis (OIA) were used to get qualitative and quantitative information about mineralogy, texture and pore network structure. Complementary analyses by X-ray fluorescence (XRF) and X-ray diffraction (XRD) were performed to refine the mineralogical information and to obtain whole rock geochemical data. Furthermore, mercury injection capillary pressure analysis (MICP), the gas permeameter test (GPT) and the hydraulic test (HT) were applied to assess the potential storage capacity and the facility of fluid flow through the rocks. Both of these factors have an outstanding importance in the determination of CO 2 reservoir potential. The applied petrophysical and petrographic methods allowed an exhaustive characterization of the samples and a preliminary assessment of their potential as a CO 2 reservoir. The studied conglomerates and sandstones have a porosity range of 8-26% with a dominant pore size range of 80-500 µm. The grain skeleton consists of quartz (95%), very minor potassium feldspars (orthoclase) and a small amount of mica (muscovite and chlorite). According to these preliminary results, among the studied varieties, the Escucha sandstones have the most favorable properties for CO 2 geological storage at the rock matrix scale.

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Pore Space Quantification of Sedimentary Rocks before-after Supercritical CO2 Interaction by Optical Image Analysis

et al. 2017

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Qualitative and quantitative changes in detrital reservoir rocks caused by CO<sub>2</sub>–brine–rock interactions during first injection phases (Utrillas sandstones, northern Spain)

Cited by 7 publications

References 53 publications

Mineral Carbonation of CO2 in Mafic Plutonic Rocks, II—Laboratory Experiments on Early-Phase Supercritical CO2‒Brine‒Rock Interactions

Mineral Carbonation of CO2 in Mafic Plutonic Rocks, II—Laboratory Experiments on Early-Phase Supercritical CO2‒Brine‒Rock Interactions

Petrographic and Petrophysical Characterization of Detrital Reservoir Rocks for CO2 Geological Storage (Utrillas and Escucha Sandstones, Northern Spain)

Pore Space Quantification of Sedimentary Rocks before-after Supercritical CO2 Interaction by Optical Image Analysis

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