CO2作用下碳酸盐岩物性及孔喉结构变化特征

doi:10.13809/j.cnki.cn32-1825/te.2025.04.005

摘要/Abstract

摘要：

在实现中国“双碳”目标过程中，咸水层封存CO₂是一个重要途径。中国西南地区咸水层资源丰富，CO₂封存潜力巨大，而现阶段咸水层封存CO₂所引起的储层特征变化主要局限于岩石的宏观阶段，缺乏从微观尺度对CO₂-水-岩反应前后岩石的孔隙结构特征变化进行表征。以四川盆地川中磨溪地区嘉陵江组二段碳酸盐岩咸水层为例，通过室内模拟地层温压条件（压力69 MPa、温度97 ℃），开展20组CO₂-水-岩相互作用实验，利用X射线衍射、核磁共振、扫描电子显微镜、计算机断层扫描等分析手段，深入探究CO₂作用下碳酸盐岩物性和孔喉结构的演变特征。研究结果表明：随着反应的进行，岩石中黏土矿物、石英等物质占比逐渐增加，长石类矿物的质量分数显著减少，方解石的质量分数先减小后增大，而白云石的质量分数则呈现先升高后降低的趋势。矿物的溶蚀作用改变了碳酸盐岩的孔喉结构，孔隙间连通性增强，孔喉半径增大，孔隙度和渗透率增加，进而增大了储层的孔隙空间。且CO₂体积分数越高，碳酸盐岩的物性和孔喉结构的变化越显著。纯CO₂作用下，碳酸盐岩反应50 d后，其孔隙度和渗透率分别增大了18.64%和522.03%。通过揭示CO₂-水-岩反应对碳酸盐岩孔渗性及矿物组成的显著影响，为咸水层封存CO₂提供了宝贵的数据支持。

关键词: CO₂封存, 咸水层, 碳酸盐岩, 水岩反应, 岩石微观分析

Abstract:

As China advances toward its dual-carbon goals, CO₂ sequestration in saline aquifers is a key pathway. Saline aquifers in southwestern China are rich in resources and hold great potential for CO₂ sequestration. However, current studies on reservoir changes caused by CO₂ sequestration in saline aquifers are mainly limited to the macroscopic scale, with a lack of characterization of changes in the pore structure of rocks before and after CO₂-water-rock reactions at the microscopic scale. Taking the carbonate rock saline aquifer of the second member of the Jialingjiang Formation in the Moxi area, central Sichuan Basin, as an example, 20 sets of CO₂-water-rock interaction experiments were conducted through laboratory simulation of formation pressure (69 MPa) and temperature (97 ℃). Analytical techniques such as X-ray diffraction, nuclear magnetic resonance, scanning electron microscopy, and computed tomography were used to investigate in depth the evolution of physical properties and pore-throat structures of the carbonate rocks under the influence of CO₂. The results showed that: as the reaction progressed, the proportions of clay minerals and quartz in the rock gradually increased, the mass fraction of feldspar minerals decreased significantly, the mass fraction of calcite first decreased and then increased, while the mass fraction of dolomite showed a trend of first increasing and then decreasing. The dissolution of minerals altered the pore-throat structure of the carbonate rock, enhancing pore connectivity, enlarging the pore-throat radius, and increasing porosity and permeability, thereby expanding the pore space within the reservoir. Moreover, the higher the volume fraction of CO₂, the more significant the changes in the physical properties and pore-throat structures of the carbonate rock. Under the influence of pure CO₂, after 50 days of reaction, the porosity and permeability of the carbonate rock increased by 18.64% and 522.03%, respectively. By revealing the significant effects of CO₂-water-rock reactions on the porosity, permeability, and mineral composition of carbonate rocks, these findings provide valuable data support for CO₂ sequestration in saline aquifers.

Key words: CO₂ sequestration, saline aquifer, carbonate rock, water-rock reaction, microscopic analysis of rocks

中图分类号:

TE122

吴潇,刘润昌. CO₂作用下碳酸盐岩物性及孔喉结构变化特征[J]. 油气藏评价与开发, 2025, 15(4): 571-578.

WU Xiao,LIU Runchang. Variation characteristics of physical properties and pore-throat structure of carbonate rocks under the influence of CO₂[J]. Petroleum Reservoir Evaluation and Development, 2025, 15(4): 571-578.

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岩样编号	长度/cm	直径/cm	干重/g	孔隙度/%	渗透率/10^-3 μm²	CO₂体积分数/%
M1	3.97	2.51	48.58	12.22	0.010 0	0
M2	3.97	2.51	49.16	11.54	0.009 2	20
M3	3.97	2.51	52.97	11.04	0.010 6	40
M4	3.98	2.52	52.35	10.51	0.009 5	70
M5	3.98	2.52	51.76	10.12	0.009 0	100

原始矿物	反应方程式	产出物
方解石	CaCO₃+H⁺→Ca²⁺+HCO	钙离子
白云石	CaMg（CO₃）₂+2H⁺→Ca²⁺+Mg²⁺+2HCO	钙离子、镁离子
钠长石	2NaAlSi₃O₈+3H₂O+2CO₂→Al₂Si₂O₅（OH）₄+2Na⁺+4SiO₂+2HCO	石英、高岭石
钾长石	2KAlSi₃O₈+2H⁺+9H₂O→Al₂Si₂O₅（OH）₄+2K⁺+4H₄SiO₄	高岭石、正硅酸
钙长石	CaAl₂Si₂O₈+H₂CO₃+H₂O→CaCO₃+Al₂Si₂O₅（OH）₄	高岭石、碳酸钙

CO₂作用下碳酸盐岩物性及孔喉结构变化特征

Variation characteristics of physical properties and pore-throat structure of carbonate rocks under the influence of CO₂

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