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Environmental Earth Sciences

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01.03.2015 | Original Article

Modelling CO₂-brine-rock interactions in the Upper Paleozoic formations of Ordos Basin used for CO₂ sequestration

verfasst von: Hejuan Liu, Zhengmeng Hou, Patrick Were, Yang Gou, Lun Xiong, Xiaoling Sun

Erschienen in: Environmental Earth Sciences | Ausgabe 5/2015

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Abstract

Subsurface immobilization and conversion of CO₂ into solid mineral phases in deep siliciclastic saline formations containing silicate minerals, commonly known as “mineral trapping”, is gaining research attention as a significant option to reduce CO₂ emissions in the atmosphere. Although mineral trapping of CO₂ is a long-term process, a combination of short-term results from both laboratory experiments and numerical simulations can lead to some general understanding of the required long-term CO₂ sequestration mechanisms. This is a 100 year preliminary batch simulation study of four sandstone samples, under CO₂ saturated water at 75 °C from the Upper Permian formations in the Ordos Basin, using the TOUGHREACT/ECO2N module to simulate the CO₂-brine-rock interaction processes in deep siliciclastic multilayered saline aquifers. The samples approximately correspond to the four target saline formations selected by the Shenhua Group for a CO₂ sequestration field demonstration project in the Ordos Basin, PR China. Preliminary simulation results show that the initial salinity of formation brine plays a significant role in determining the amount of CO₂ that will be sequestered by solubility or mineral trapping in a deep saline aquifer. Minimal differences between experimental results and numerical calculation occur in low salinity waters, and significantly larger differences in high salinity waters, which is still under the maximum acceptable difference between experimental and computed data (10 %). The upper Liujiagou formation, with the highest level of salinity (ca. 88.7 g/L TDS) and lowest level of CO₂ solubility, offers the highest mineral trapping capacity, with a maximum carbonate mineral storage of ca. 0.7 kg/m³ of bulk rock over a 100 year period. Regardless of the initial acidity or alkalinity of the aquifer brine, injection of CO₂ will inflict a sudden drop in pH of the brine to acidity levels in a range of 3.0–4.6. The subsequent amount of dissolved and precipitated minerals, arising from the CO₂-brine-rock interaction, is site specific and mainly dependent on initial aquifer mineralogy and brine composition.

Vorheriger Artikel Estimation of aquifer parameters using tide-induced groundwater level measurements in a coastal confined aquifer

Nächster Artikel Quantification of water table dynamics as a reference for impact assessment of ecohydrological enhancement measures in a dune area in Belgium

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Titel: Modelling CO2-brine-rock interactions in the Upper Paleozoic formations of Ordos Basin used for CO2 sequestration
verfasst von: Hejuan Liu
Zhengmeng Hou
Patrick Were
Yang Gou
Lun Xiong
Xiaoling Sun
Publikationsdatum: 01.03.2015
Verlag: Springer Berlin Heidelberg
Erschienen in: Environmental Earth Sciences / Ausgabe 5/2015
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI: https://doi.org/10.1007/s12665-014-3571-4

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