Eau Claire组的岩性、矿物学和岩石物理特征:储碳系统密封的复杂性

Q2 Earth and Planetary Sciences
Ryan J. Neufelder, B. Bowen, R. Lahann, J. Rupp
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引用次数: 22

摘要

对与温室气体排放有关的潜在气候变化的担忧促使世界各地的研究人员评估地质储存二氧化碳的可行性。在美国伊利诺斯盆地,寒武系西蒙山砂岩被定位为碳捕获和储存(CCS)的储层。在该CCS系统中,Eau Claire组有望成为防止CO2柱向上运移的主要密封层;然而,很少有人做过具体的工作来确定它作为密封的功能有多好。虽然Eau Claire组的横向范围和厚度,以及其普遍的低渗透率,无疑使其成为这一能力的首选,但主要的沉积结构和矿物学,这是该单元岩石物理性质的基本控制因素,仍然没有得到很好的约束。因此,本研究的目的是研究Eau Claire组的岩性、矿物学和岩石物理性质,以表征其在CCS系统中作为功能密封的潜力。通过结合岩石学、反射光谱、x射线衍射、地球化学和岩石物理分析,对伊利诺伊盆地7口井的66个Eau Claire地层岩心样品进行了描述。分析表明,奥克莱尔组包含砂岩、净粉砂岩、泥质粉砂岩、粉质泥岩和页岩5种不同的岩相,其组构和矿物学上的细尺度非均质性对岩石物性有较大影响。孔隙度、渗透率和进入压力数据表明,Eau Claire组中的一些(但不是全部)岩相有能力作为合适的CCS密封。丰富的自生矿物和溶蚀结构表明,过去的多代流体-岩石相互作用发生在Eau Claire组内,表明该组的大部分地层表现为流体管道而不是密封。在CCS系统中可能发生反应的矿物(包括碳酸盐、海绿石和绿泥石)在Eau Claire组中很常见。在碳酸的存在下,这些相和其他相的溶解可能会危及装置的密封完整性。尽管封存特性存在复杂性,但CCS系统的动力学和新矿物沉淀的潜力应该使Eau Claire组能够起到足够的封存作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Lithologic, mineralogical, and petrophysical characteristics of the Eau Claire Formation: Complexities of a carbon storage system seal
Concerns about potential climate change related to greenhouse gas emissions have spurred researchers across the world to assess the viability of geologic storage of CO2. In the Illinois Basin in the United States, the Cambrian Mount Simon Sandstone has been targeted as a reservoir for carbon capture and storage (CCS). In this CCS system, the Eau Claire Formation is expected to serve as the primary seal to prevent upward migration of the CO2 plume; however, little work has been done to specifically determine how well it will function as a seal. Although the lateral extent and thickness of the Eau Claire Formation, along with its generally low permeability, certainly make it a prime candidate to serve in this capacity, the primary depositional fabric and mineralogy, which are the fundamental controls on the petrophysical charter of this unit, remain poorly constrained. Therefore, the purpose of this study is to investigate the lithologic, mineralogical, and petrophysical properties of the Eau Claire Formation in an effort to characterize its potential as a functional seal in a CCS system. Sixty-six core-derived Eau Claire Formation samples from seven wells within the Illinois Basin are described using a combination of petrography, reflectance spectroscopy, x-ray diffraction, geochemical, and petrophysical analyses. These analyses show that the Eau Claire Formation contains five different lithofacies (sandstone, clean siltstone, muddy siltstone, silty mudstone, and shale) with fine-scale heterogeneities in fabric and mineralogy that greatly influence the petrophysical properties. Porosity, permeability, and entry-pressure data suggest that some, but not all, lithofacies within the Eau Claire Formation have the capability to serve as a suitable CCS seal. Abundant authigenic minerals and dissolution textures indicate that multiple generations of past fluid-rock interactions have occurred within the Eau Claire Formation, demonstrating that much of the formation has behaved as a fluid conduit instead of as a seal. Minerals that would be potentially reactive in a CCS system (including carbonate, glauconite, and chlorite) are common in the Eau Claire Formation. Dissolution of these and other phases in the presence of carbonic acid could potentially jeopardize the sealing integrity of the unit. Although complexities in the sealing properties exist, the dynamics of the CCS system and the potential for precipitation of new minerals should allow the Eau Claire Formation to serve as an adequate seal.
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来源期刊
Environmental Geosciences
Environmental Geosciences Earth and Planetary Sciences-Earth and Planetary Sciences (all)
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