Mineral and fluid transformation of hydraulically fractured shale: case study of Caney Shale in Southern Oklahoma

IF 3.9 2区 工程技术 Q3 ENERGY & FUELS Geomechanics and Geophysics for Geo-Energy and Geo-Resources Pub Date : 2024-07-31 DOI:10.1007/s40948-024-00835-0
Gabriel A. Awejori, Wenming Dong, Christine Doughty, Nicolas Spycher, Mileva Radonjic
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Abstract

This study explores the geochemical reactions that can cause permeability loss in hydraulically fractured reservoirs. The experiments involved the reaction of powdered-rock samples with produced brines in batch reactor system at temperature of 95 °C and atmospheric pressure for 7-days and 30-days respectively. Results show changes in mineralogy and chemistry of rock and fluid samples respectively, therefore confirming chemical reactions between the two during the experiments. The mineralogical changes of the rock included decreases of pyrite and feldspar content, whilst carbonate and illite content showed an initial stability and increase respectively before decreasing. Results from analyses of post-reaction fluids generally corroborate the results obtained from mineralogical analyses. Integrating the results obtained from both rocks and fluids reveal a complex trend of reactions between rock and fluid samples which is summarized as follows. Dissolution of pyrite by oxygenated fluid causes transient and localized acidity which triggers the dissolution of feldspar, carbonates, and other minerals susceptible to dissolution under acidic conditions. The dissolution of minerals releases high concentrations of ions, some of which subsequently precipitate secondary minerals. On the field scale, the formation of secondary minerals in the pores and flow paths of hydrocarbons can cause significant reduction in the permeability of the reservoir, which will culminate in rapid productivity decline. This study provides an understanding of the geochemical rock–fluid reactions that impact long term permeability of shale reservoirs.

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水力压裂页岩的矿物和流体转化:俄克拉荷马州南部卡尼页岩案例研究
本研究探讨了可导致水力压裂储层渗透率损失的地球化学反应。实验包括在批量反应器系统中,在温度为 95 ℃、压力为大气压的条件下,将粉末状岩石样本与生产的盐水分别反应 7 天和 30 天。结果表明,岩石和流体样品的矿物学和化学性质分别发生了变化,从而证实了两者在实验过程中发生了化学反应。岩石的矿物学变化包括黄铁矿和长石含量的减少,而碳酸盐和伊利石含量在减少之前分别表现出最初的稳定和增加。反应后流体的分析结果与矿物分析结果基本吻合。综合从岩石和流体中获得的结果,可以发现岩石和流体样本之间反应的复杂趋势,总结如下。含氧流体对黄铁矿的溶解会造成短暂的局部酸性,从而引发长石、碳酸盐和其他在酸性条件下易溶解的矿物的溶解。矿物溶解会释放出高浓度的离子,其中一些离子随后会沉淀出次生矿物。在油田规模上,碳氢化合物在孔隙和流道中形成的次生矿物会导致储层渗透率显著下降,最终导致生产率迅速下降。这项研究有助于了解影响页岩储层长期渗透性的岩石-流体地球化学反应。
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来源期刊
Geomechanics and Geophysics for Geo-Energy and Geo-Resources
Geomechanics and Geophysics for Geo-Energy and Geo-Resources Earth and Planetary Sciences-Geophysics
CiteScore
6.40
自引率
16.00%
发文量
163
期刊介绍: This journal offers original research, new developments, and case studies in geomechanics and geophysics, focused on energy and resources in Earth’s subsurface. Covers theory, experimental results, numerical methods, modeling, engineering, technology and more.
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