富有机页岩中的氢地质储藏:对缓冲气在有机纳米多孔系统内氢气积累中的作用的重要见解

SPE Journal Pub Date : 2024-06-01 DOI:10.2118/221468-pa
Saad Alafnan
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引用次数: 0

摘要

贫化页岩层具有地质储氢的潜力。然而,储氢机制非常复杂,受到多种因素的影响,包括矿物学、孔径分布、残留碳氢化合物以及缓冲气的选择。本研究旨在研究氢在这种多尺度孔隙系统中的分布,重点是了解氢如何在有机纳米多孔网络中积聚。这些见解对于长期储存和回收评估至关重要。通过分子模拟,构建了由纳米多孔角质和不同大小的纳米孔组成的代表性有机物。考虑到多种氢气注入方案,对有机系统在天然气残留量存在时的氢气摄入量进行了量化。尽管氢气与天然气的化学亲和力更强,但氢气在所有尺寸的孔隙中都有积累,即使是最小的孔隙,这可能有利于长期储存,但会阻碍快速回收。此外,研究还扩展到了缓冲气体在有机结构中氢气积累中的作用。研究发现,引入甲烷和二氧化碳等缓冲气体可减少纳米孔隙中的氢气摄入量,其中二氧化碳的效果最好,因为它对角质有更强的吸引力。另一方面,氮气的影响相对较小。这些结果与分析所有系统的非键能时观察到的趋势一致。本研究报告的结果为影响页岩层有机成分中氢积累的因素提供了重要启示,有助于优化枯竭页岩气藏中的氢地质封存设计。
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Hydrogen Geostorage in Organic-Rich Shales: Critical Insights Into the Role of Cushion Gas in Hydrogen Accumulation within Organic Nanoporous Systems
Depleted shale formations have the potential for hydrogen geostorage. The storage mechanisms, however, are complex and influenced by several factors including mineralogy, pore size distribution, residual hydrocarbons in place, and the choice of cushion gas. This study aims to investigate hydrogen distribution within this multiscale pore system, with a focus on understanding how hydrogen accumulates in the organic nanoporous network. Such insights are critical for the long-term storage and recovery assessments. Using molecular simulations, representative organic matter comprising nanoporous kerogen and nanopores of different sizes was constructed. Hydrogen intake of the organic system in the presence of residual amount of natural gas was quantified, considering multiple hydrogen injection scenarios. Despite stronger chemical affinity toward natural gas, hydrogen accumulated in all pore sizes, even the smallest, potentially beneficial for long-term storage but hindering rapid recovery. Moreover, the study was extended to investigate the role of cushion gas in the accumulation of hydrogen in organic structures. It was found that introducing cushion gases, such as methane and carbon dioxide, reduces hydrogen intake in the nanopores, with carbon dioxide being the most effective due to its stronger attraction to kerogen. Nitrogen, on the other hand, had relatively lower impact. The results were consistent with the observed trends in the analysis of the nonbonding energy of all systems. The results reported in this study provide critical insights into the factors influencing hydrogen accumulation in the organic constituents of shale formations for an optimized design of hydrogen geostorage in depleted shale gas reservoirs.
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