Importance of mineral surface areas in Rotliegend sandstones for modeling CO2–water–rock interactions

Investigations of Rotliegend sandstones from the NE Netherlands have been carried out to determine the mineralogical composition and spatial mineral distribution, specific mineral and whole rock surface areas and the integration of these results in geochemical water–rock–CO2 simulations. Therefore,...

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Bibliographic Details
Published in:Chemical geology 2014-06, Vol.378-379, p.89-109
Main Authors: Waldmann, Svenja, Busch, Andreas, van Ojik, Kees, Gaupp, Reinhard
Format: Article
Language:English
Subjects:
CO2 storage
Diagenesis
Effective mineralogy
Geochemical modeling
Grains
Mathematical models
Mineralogy
Minerals
Porosity
Rock
Rotliegend
Sandstones
Specific surface area
Surface area
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Summary:Investigations of Rotliegend sandstones from the NE Netherlands have been carried out to determine the mineralogical composition and spatial mineral distribution, specific mineral and whole rock surface areas and the integration of these results in geochemical water–rock–CO2 simulations. Therefore, two scenarios were considered: (1) volumetric rock composition (derived from point counting on thin sections) and (2) effective mineralogy (derived from 2D pore lining image analysis) data which represent the percentage amount of each mineral phase exposed within open (or accessible) pores. Specific mineral surface areas were defined for each mineral phase, respectively and integrated in both model scenarios. Based on point counting data the volumetric compositions of the sandstones are dominated by the mineralogy of detrital grains like quartz and K-feldspar. Authigenic minerals, esp. clays, volumetrically make up a small portion of the bulk rock volume only but are exposed due to their small crystal size (nm- to μm-scale) and a large specific surface area (13 to 195m2/g) in comparison to e.g. feldspar grains (0.03 to 1.79m2/g). Hence the size, distribution and accessibility of detrital and authigenic minerals regulate the availability of chemical species for water–rock interactions in the pore space. The effective mineralogy of the sandstones is a function of the presence of grain covering and pore-filling authigenic minerals. In the two Rotliegend sandstones studied, approximately 23% and 43% of the detrital grains are covered by cements blocking the grain surface areas accessible for potential water–rock interactions. These minerals are Fe-oxide, clay cutans (mainly illite), kaolinite, quartz, carbonate (dolomite, ankerite and siderite), sulfate (anhydrite and barite) and galena. The specific surface area (SSA) of each mineral was calculated using (electron) microscopy to determine the sample geometry (e.g. size, thickness) and standard density values. For the volumetric and effective mineralogy data the total specific surface area of the bulk rock was calculated by summing the specific mineral surface areas in relation to their relative content in the rock, as determined using X-ray diffraction. These results were compared to surface area values determined using low pressure N2 adsorption (BET method) of the bulk rock (mean value 1.4m2/g). It is shown that the SSA values using the effective mineralogy approach (mean value of 0.46m2/g) are closer to the whol
ISSN:0009-2541
1872-6836
DOI:10.1016/j.chemgeo.2014.03.014