Experimental tests and modeling of CO2 and H2S co-sequestration in saline aquifers

IF 3.7 2区地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Marine and Petroleum Geology Pub Date : 2024-11-13 DOI:10.1016/j.marpetgeo.2024.107196

Krzysztof Labus

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Abstract

A simulation study and a series of autoclave experiments were performed, reproducing gas-rock-water systems under reservoir conditions, after injection of CO₂ and the mixture of CO₂ with H₂S into rocks representing the Upper Silesian Coal Basin and the adjacent Małopolska Block (Central Europe). The water-rock-gas interactions were modeled in two stages: the first–aimed at simulating the short-term changes in system impacted by the gas injection, and the second–long-term effects of sequestration.

On the basis of the simulations, the reactions behind mineral transformations were identified. These phenomena are different for the injection of CO₂ alone. and CO₂+H₂S mixtures, resulting in the formation of secondary minerals responsible for mineral sequestration. Depending on the original mineral composition of the rock, in the case of pure CO₂, these are mainly carbonate minerals siderite, dawsonite, magnesite, dolomite and calcite, while in the case of mixture injection: elemental sulfur, sulfur sulfides–pyrite and pyrrhotite.

In experiments with the H₂S+CO₂ mixture, dissolution of skeletal grains was observed, which was most visible in the case of carbonates, feldspars, and chlorites. The analysis of rocks containing hematite revealed the formation of elemental sulfur surrounded by FeS₂ crystals, which had not been previously reported.

The experiments generally confirmed the interactions in gas-rock-water systems identified by numerical simulation. This allowed to estimate the amount of mineral phases precipitated or dissolved in the analyzed reactions, and consequently the impact on changes in porosity and the amount of sequestered carbon dioxide and sulfur.

In samples abundant in carbonate minerals (the Dębowiec Formation psephites), the decomposition of ankerite, due to the injection of CO₂+H₂S, is not compensated for by the precipitation of sufficient amounts of other carbonates, which leads to the desequestration process–CO₂ release.

Based on the calculations, it was found that the potentially most favorable conditions for the sequestration occur in the Paralic Series mudstones, rich in chlorites–a maximum of 22.36 kg CO₂/m³ and 12.50 kg S/m³, trapping capacity after 10,000 years of storage.

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含盐含水层中二氧化碳和 H2S 共同封存的实验测试和建模

在上西里西亚煤炭盆地和邻近的小波兰区块（中欧）的岩石中注入二氧化碳和二氧化碳与 H2S 的混合物后，进行了模拟研究和一系列高压釜实验，再现了储层条件下的气体-岩石-水系统。水-岩石-气体相互作用模型分为两个阶段：第一阶段旨在模拟受气体注入影响的系统的短期变化，第二阶段则是封存的长期影响。这些现象在单独注入 CO2 和注入 CO2+H2S 混合物时有所不同，从而形成了负责矿物封存的次生矿物。根据岩石的原始矿物成分，在注入纯 CO2 的情况下，这些矿物主要是碳酸盐矿物菱铁矿、褐铁矿、菱镁矿、白云石和方解石，而在注入混合物的情况下：元素硫、硫化物-黄铁矿和黄铁矿。在使用 H2S+CO2 混合物的实验中，观察到骨架颗粒溶解，这在碳酸盐、长石和绿泥石中最为明显。对含有赤铁矿的岩石进行的分析表明，形成了被 FeS2 晶体包围的元素硫，这在以前的报道中从未有过。在富含碳酸盐矿物的样本中（登博维耶克地层的辉绿岩），由于注入 CO2+H2S 而导致的辉绿岩分解并没有得到足够数量的其他碳酸盐沉淀的补偿，这就导致了脱碳过程--CO2 的释放。根据计算发现，在富含绿泥石的帕拉里克系列泥岩中，封存条件可能最为有利--封存 10,000 年后的最大封存能力为 22.36 千克 CO2/m3 和 12.50 千克 S/m3。

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来源期刊

Marine and Petroleum Geology 地学-地球科学综合

CiteScore

8.80

自引率

14.30%

发文量

475

审稿时长

63 days

期刊介绍： Marine and Petroleum Geology is the pre-eminent international forum for the exchange of multidisciplinary concepts, interpretations and techniques for all concerned with marine and petroleum geology in industry, government and academia. Rapid bimonthly publication allows early communications of papers or short communications to the geoscience community. Marine and Petroleum Geology is essential reading for geologists, geophysicists and explorationists in industry, government and academia working in the following areas: marine geology; basin analysis and evaluation; organic geochemistry; reserve/resource estimation; seismic stratigraphy; thermal models of basic evolution; sedimentary geology; continental margins; geophysical interpretation; structural geology/tectonics; formation evaluation techniques; well logging.