二氧化碳密封能力:结构或成分控制?来自俄克拉何马州狭长地带的案例研究*

Q2 Earth and Planetary Sciences Environmental Geosciences Pub Date : 2015-06-01 DOI:10.1306/EG.04021515002
C. Crânganu, H. Soleymani
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引用次数: 3

摘要

在地质介质中长期进行二氧化碳捕获与封存(CCS)所面临的挑战之一是确定盖层的密封能力。如果注入储存库的超临界二氧化碳的压力超过了盖层的密封能力,则泄漏的二氧化碳可能会进入其他多孔地层,危及储存库地层,甚至可能回到大气中,这样的封存过程就变得无效了。二氧化碳密封能力由两组参数控制:(1)结构(如孔喉大小、分布、几何形状和分选等);中位粒度、孔隙度、生物扰动程度、比表面积、基质粘土矿物的首选取向、取向和有机颗粒比例)和(2)组成(矿物学含量、柔软、可变形矿物颗粒与刚性颗粒的比例、有机质含量、碳酸盐含量、粉砂含量、胶结性、延展性、压实性和灰分含量)。本研究的主要目标是研究上述几个参数,并估计它们各自对密封能力的贡献,以更好地了解其在页岩和碳酸盐岩中的作用。为了评估结构和成分性质对最大保留柱高度的影响,我们从俄克拉何马州狭长地带的三个县(Cimarron, Texas和Beaver)的盖层地层中收集了30个具有代表性的岩心样本。之所以选择该研究区域,是因为它拥有三个储量超过3500万桶的枯竭天然气田,并且位于通往德克萨斯州北部、堪萨斯州南部和俄克拉荷马州北部一些重要的固定气源的十字路口。我们使用压汞孔隙度法、扫描电镜(SEM)、Sedigraph能谱(EDS)、x射线衍射(XRD)、brunauer - emmet - teller比表面积和总有机碳(TOC)测量来评估所收集样品的结构和组成特性。本研究中使用的样品柱高范围在0.2至1358米(0.66至4455英尺)之间。柱的平均高度为351米(1152英尺)。大约1400米(4593英尺)的深度间隔可以达到相对较高的柱高,最高可达1200米(3937英尺)。上述层段主要由Cherokee组和Morrowan组(页岩封)组成。采用主成分分析(PCA)来推断纹理和成分参数之间可能存在的关系。一般来说,我们的样品组成(页岩、碳酸盐岩和砂岩)表明对盖层密封能力的控制相对较强,尽管页岩样品的个别矿物组成似乎与保留柱高度无关。同时,许多结构参数对碳酸盐岩盖层的封闭能力起着重要的决定作用。
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Carbon dioxide sealing capacity: Textural or compositional controls? A case study from the Oklahoma Panhandle*
One of the challenges confronting carbon dioxide capture and sequestration (CCS) in geologic media over extended periods of time is determining the caprock sealing capacity. If the pressure of supercritical carbon dioxide injected in the repository overcomes the caprock sealing capacity, leaking of may enter other porous formations, compromising the storage formation, or even may go back to the atmosphere, and thus the process of sequestration becomes futile. Carbon dioxide sealing capacity is controlled by two groups of parameters: (1) texture (e.g., the pore-throat size, distribution, geometry, and sorting; median grain size, porosity, degree of bioturbation, specific surface area, preferred orientation of matrix clay minerals, orientation, and aspect of ratio of organic particles) and (2) composition (mineralogical content, proportion of soft, deformable mineral grains to rigid grains, organic matter content, carbonate content, silt content, cementation, ductility, compaction, and ash content). The primary goal of this study was to investigate several parameters listed above and to estimate their respective contributions to sealing capacity to better understand its role in shale and carbonates. To assess the effect of textural and compositional properties on maximum retention column height, we collected 30 representative core samples from caprock formations in three counties (Cimarron, Texas, and Beaver) in the Oklahoma Panhandle. The study area was chosen because it hosts three depleted gas fields with a storage capacity of more than 35 million bbl and is situated at a crossroad leading to some significant stationary sources from North Texas, South Kansas, and northern Oklahoma. We used mercury injection porosimetry, scanning electron microscopy (SEM), Sedigraph energy dispersive spectra (EDS), x-ray diffraction (XRD), Brunauer–Emmett–Teller-specific surface area, and total organic carbon (TOC) measurements to assess textural and compositional properties of collected samples. The range of column height for the samples used in this study is between 0.2 and 1358 m (0.66 and 4455 ft). The average column height is 351 m (1152 ft). The depth interval approximately 1400 m (4593 ft) could reach relatively high values of column height, up to 1200 m (3937 ft). The above-mentioned interval is composed of mainly Cherokee and Morrowan Formations (shale seals). Principal component analysis (PCA) was carried out to infer the possible relationships between textural and compositional parameters. Generally, composition of our samples (shales vs. carbonates and sandstones) indicates a relatively stronger control on caprock sealing capacity, although individual mineral makeup of shale samples seems not correlated with retention column heights. In the same time, many textural parameters play a significant role in determining the sealing capacity of carbonate caprocks.
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Environmental Geosciences
Environmental Geosciences Earth and Planetary Sciences-Earth and Planetary Sciences (all)
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