Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer

Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer

CO2 mineralization is a long-term and secure solution for geological CO2 storage that primarily depends on the CO2–brine–rock interaction during CO2 sequestration in subsurface formations. In this study, lab experiments were conducted to investigate the CO2–brine–rock interaction over short timescal...

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Main Authors: Bo Liu, Fangyuan Zhao, Jinpeng Xu, Yueming Qi
Format: Article
Language:English
Published: MDPI AG 2019-01-01
Series:Sustainability
Subjects:
experiment
simulation
CO2–brine–rock interaction
CO2 sequestration
saline aquifer
Online Access:http://www.mdpi.com/2071-1050/11/2/317
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spelling doaj-d9c01b1f4a7642aa93aa7bf23db7ebe72020-11-24T21:06:14ZengMDPI AGSustainability2071-10502019-01-0111231710.3390/su11020317su11020317Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline AquiferBo Liu0Fangyuan Zhao1Jinpeng Xu2Yueming Qi3School of Resources and Geosciences, China University of Mining and Technology, Xuzhou 221116, ChinaBMILP Science and Technology Development Co., Ltd., Beijing 100054, ChinaSchool of Resources and Geosciences, China University of Mining and Technology, Xuzhou 221116, ChinaSchool of Resources and Geosciences, China University of Mining and Technology, Xuzhou 221116, ChinaCO2 mineralization is a long-term and secure solution for geological CO2 storage that primarily depends on the CO2–brine–rock interaction during CO2 sequestration in subsurface formations. In this study, lab experiments were conducted to investigate the CO2–brine–rock interaction over short timescales, and numerical simulations were performed to reveal dynamic interactions and equilibrium interactions by applying TOUGHREACT and PHREEQC, respectively. In the experiments, the main ions of HCO3− and Ca2+ were detected in the solution, and calcite dissolution and dawsonite precipitation were observed from SEM images. The simulation results showed that the CO2 dissolution and the solution pH were affected by the temperatures, pressures, types of solutions, and solution concentrations and were further influenced by mineral dissolution and precipitation. The results of the equilibrium simulation showed that the dissolved minerals were albite, anhydrite, calcite, Ca-montmorillonite, illite, K-feldspar, and chlorite, and the precipitated minerals were dolomite, kaolinite, and quartz, which led to HCO3−, K+, and Na+ being the main ions in solutions. The results of the dynamic simulation showed that calcite and dolomite dissolved in the early period, while other minerals began to dissolve or precipitate after 100 years. The dissolved minerals were mainly albite, kaolinite, K-feldspar, and chlorite, and precipitated minerals were Ca-montmorillonite, illite, and quartz. Anhydrite and pyrite did not change during the simulation period, and the main ions were HCO3−, Na+, Ca2+, and Mg2+ in the simulation period. This study provides an effective approach for analyzing the CO2–brine–rock interaction at different stages during CO2 storage, and the results are helpful for understanding the CO2 mineralization processes in deep saline aquifers.http://www.mdpi.com/2071-1050/11/2/317experimentsimulationCO2–brine–rock interactionCO2 sequestrationsaline aquifer
collection DOAJ
language English
format Article
sources DOAJ
author Bo Liu
Fangyuan Zhao
Jinpeng Xu
Yueming Qi
spellingShingle Bo Liu
Fangyuan Zhao
Jinpeng Xu
Yueming Qi
Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer
Sustainability
experiment
simulation
CO2–brine–rock interaction
CO2 sequestration
saline aquifer
author_facet Bo Liu
Fangyuan Zhao
Jinpeng Xu
Yueming Qi
author_sort Bo Liu
title Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer
title_short Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer
title_full Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer
title_fullStr Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer
title_full_unstemmed Experimental Investigation and Numerical Simulation of CO2–Brine–Rock Interactions during CO2 Sequestration in a Deep Saline Aquifer
title_sort experimental investigation and numerical simulation of co2–brine–rock interactions during co2 sequestration in a deep saline aquifer
publisher MDPI AG
series Sustainability
issn 2071-1050
publishDate 2019-01-01
description CO2 mineralization is a long-term and secure solution for geological CO2 storage that primarily depends on the CO2–brine–rock interaction during CO2 sequestration in subsurface formations. In this study, lab experiments were conducted to investigate the CO2–brine–rock interaction over short timescales, and numerical simulations were performed to reveal dynamic interactions and equilibrium interactions by applying TOUGHREACT and PHREEQC, respectively. In the experiments, the main ions of HCO3− and Ca2+ were detected in the solution, and calcite dissolution and dawsonite precipitation were observed from SEM images. The simulation results showed that the CO2 dissolution and the solution pH were affected by the temperatures, pressures, types of solutions, and solution concentrations and were further influenced by mineral dissolution and precipitation. The results of the equilibrium simulation showed that the dissolved minerals were albite, anhydrite, calcite, Ca-montmorillonite, illite, K-feldspar, and chlorite, and the precipitated minerals were dolomite, kaolinite, and quartz, which led to HCO3−, K+, and Na+ being the main ions in solutions. The results of the dynamic simulation showed that calcite and dolomite dissolved in the early period, while other minerals began to dissolve or precipitate after 100 years. The dissolved minerals were mainly albite, kaolinite, K-feldspar, and chlorite, and precipitated minerals were Ca-montmorillonite, illite, and quartz. Anhydrite and pyrite did not change during the simulation period, and the main ions were HCO3−, Na+, Ca2+, and Mg2+ in the simulation period. This study provides an effective approach for analyzing the CO2–brine–rock interaction at different stages during CO2 storage, and the results are helpful for understanding the CO2 mineralization processes in deep saline aquifers.
topic experiment
simulation
CO2–brine–rock interaction
CO2 sequestration
saline aquifer
url http://www.mdpi.com/2071-1050/11/2/317
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AT fangyuanzhao experimentalinvestigationandnumericalsimulationofco2brinerockinteractionsduringco2sequestrationinadeepsalineaquifer
AT jinpengxu experimentalinvestigationandnumericalsimulationofco2brinerockinteractionsduringco2sequestrationinadeepsalineaquifer
AT yuemingqi experimentalinvestigationandnumericalsimulationofco2brinerockinteractionsduringco2sequestrationinadeepsalineaquifer
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