Chemical effects of carbon dioxide sequestration in the Upper Morrow Sandstone in the Farnsworth, Texas, hydrocarbon unit

Q2 Earth and Planetary Sciences Environmental Geosciences Pub Date : 2016-06-01 DOI:10.1306/EG.09031515006
B. Ahmmed, M. Appold, Tianguang Fan, B. McPherson, R. Grigg, M. White
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引用次数: 22

Abstract

Numerical geochemical modeling was used to study the effects on pore-water composition and mineralogy from carbon dioxide (CO2) injection into the Pennsylvanian Morrow B Sandstone in the Farnsworth Unit in northern Texas to evaluate its potential for long-term CO2 sequestration. Speciation modeling showed the present Morrow B formation water to be supersaturated with respect to an assemblage of zeolite, clay, carbonate, mica, and aluminum hydroxide minerals and quartz. The principal accessory minerals in the Morrow B, feldspars and chlorite, were predicted to dissolve. A reaction-path model in which CO2 was progressively added up to its solubility limit into the Morrow B formation water showed a decrease in pH from its initial value of 7 to approximately 4.1 to 4.2, accompanied by the precipitation of small amounts of quartz, diaspore, and witherite. As the resultant CO2-charged fluid reacted with more of the Morrow B mineral matrix, the model predicted a rise in pH, reaching a maximum of 5.1 to 5.2 at a water–rock ratio of 10:1. At a higher water–rock ratio of 100:1, the pH rose to only 4.6 to 4.7. Diaspore, quartz, and nontronite precipitated consistently regardless of the water–rock ratio, but the carbonate minerals siderite, witherite, dolomite, and calcite precipitated at higher pH values only. As a result, CO2 sequestration by mineral trapping was predicted to be important only at low water–rock ratios, accounting for a maximum of 2% of the added CO2 at the lowest water–rock ratio investigated of 10:1, which corresponds to a small porosity increase of approximately 0.14% to 0.15%.
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德克萨斯州法恩斯沃斯油气单元Upper Morrow砂岩中二氧化碳封存的化学效应
采用数值地球化学模型研究了向德克萨斯州北部Farnsworth单元的pennsylvania Morrow B砂岩注入二氧化碳对孔隙水组成和矿物学的影响,以评估其长期封存二氧化碳的潜力。物种模型显示,现在的Morrow B地层水相对于沸石、粘土、碳酸盐、云母、氢氧化铝矿物和石英的组合来说是过饱和的。预测Morrow B中的主要副矿物长石和绿泥石会溶解。在一个反应路径模型中,CO2逐渐加入到Morrow B地层水中,达到其溶解度极限,结果表明pH值从初始值7下降到大约4.1到4.2,并伴有少量石英、一水硬石和辉石的沉淀。随着产生的带二氧化碳的流体与更多的Morrow B矿物基质发生反应,该模型预测pH值将上升,在水岩比为10:1时达到最大值5.1至5.2。当水岩比达到100:1时,pH值仅上升到4.6 ~ 4.7。一水硬铝石、石英和非长石的沉淀与水岩比无关,但碳酸盐矿物菱铁矿、辉石、白云石和方解石只有在较高的pH值下才会沉淀。因此,只有在低水岩比条件下,矿物捕获的CO2封存作用才会发挥重要作用,在最低水岩比为10:1的条件下,矿物捕获的CO2封存作用最多占CO2添加量的2%,这相当于孔隙度增加了约0.14%至0.15%。
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Environmental Geosciences
Environmental Geosciences Earth and Planetary Sciences-Earth and Planetary Sciences (all)
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