The impact of reactive surface area on brine-rock-carbon dioxide reactions in CO₂ sequestration

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• 作者：Hyukmin Kweon ; Milind Deo ; ^{Milind.Deo@utah.edu" class="auth_mail" title="E-mail the corresponding author}
• 关键词：Carbon dioxide sequestration ; BET surface area ; Reactive surface area
• 刊名：Fuel
• 出版年：2017
• 出版时间：15 January 2017
• 年：2017
• 卷：188
• 期：Complete
• 页码：39-49
• 全文大小：2967 K

文摘

Injection of carbon dioxide into saline aquifers is one the most promising methods for mitigating the increase in atmospheric CO₂ concentrations. Reactions of CO₂ with brine and formation rocks are important in determining the ultimate fate of CO₂. Rates of reactions of the different relevant minerals are dependent on rate constants and mineral surface area. It is important to quantify the effect of surface area on reaction rates when different types of rock samples are employed in experiments. Batch experiments with different forms of the Berea sandstone were set up and performed at high pressure (2000 psi) and reservoir temperature (60 °C) for two-week under reservoir CO₂ sequestration conditions. Experiments were performed with markedly different samples (cores, rock chips, and powdered) with progressively increased surface areas. Experiments with the different forms of sandstones showed similar trends in major minerals dissolution with increase in cation concentrations of iron, magnesium, and calcium in the effluent brine. Under realistic aquifer pressure and temperature conditions, iron chemistry plays an important role in the dissolution reactions in the Berea sandstone. Reactivities increased leading to larger cationic concentrations in brine (as determined using ICP-MS) as the surface areas increased. Morphology of the reacted volume was viewed using QEMSCAN and Micro-CT for core plug samples. These experiments helped quantity the effect of surface area (higher surface area leading to more dissolution) and revealed that reactions appear to be limited more to the surface in Berea sandstone. It was shown that the factor used to obtain geometric surface area from a core decreased when samples with higher surface areas were used. This indicated that some internal surface area became available for fragmented (fractured), and powdered samples. Mineral dissolution caused the growth and expansion of pores in Berea sandstone and surface area measurements (BET) showed that the new porosity generated was characterized by a smaller pore size distribution in comparison to the unreacted one.