Simulation of migration behavior and occurrence forms of impure CO2 in saline aquifer geological storage

doi:10.3969/j.issn.2096-1693.2026.02.007

Abstract

Abstract:

Geological carbon storage (GCS) is one of the key technologies to achieve Carbon peak and carbon neutrality goals. Since industrial-source CO₂ usually contains various impurity gases, and its purification is costly and technically challenging, these impurities are often injected into the subsurface together with CO₂ in practical engineering applications. Based on the geological characteristics of the Shiqianfeng Formation in a CCS demonstration project area, a two-dimensional geological model was established, and reactive transport simulations of impure CO₂ were conducted using the CMG-GEM compositional simulator. N₂ and H₂S were selected as representative impurity components to investigate the migration pathways, occurrence forms, and spatial distribution characteristics of impure CO₂ in the saline aquifer. The study systematically analyzed the dominant trapping mechanisms, including structural trapping, residual gas trapping, and solubility trapping, at different storage stages, and explored the role of capillary pressure in the geological storage process of impure CO₂. The simulation results indicate that during the early injection stage, CO₂ predominantly accumulates in the supercritical state at the top of the reservoir. Over time, the capillary trapping effect gradually emerges, more CO₂ is retained in the reservoir pores, promoting the continuous conversion of supercritical CO₂ into bound and dissolved forms, thereby significantly enhancing the overall storage stability and safety. CO₂ migration exhibits pronounced spatiotemporal heterogeneity: the injected gas rapidly rises under buoyancy and accumulates beneath the caprock, then gradually migrates downward under density and concentration gradients, promoting dissolution. After injection ceases, the gas spreads laterally along the base of the caprock, forming a tongue-shaped migration front with a maximum diffusion distance of approximately 650 m. The transport behaviors of the impurity components differ significantly. Due to its low solubility, N₂ tends to accumulate at the leading edge of the gas-liquid displacement front, whereas CO₂ and H₂S, with higher solubility, form dissolution-enriched zones near the injection well, reaching peak solubilities of 1.4 mol/kg-H₂O and 0.53 mol/kg-H₂O, respectively. Capillary pressure plays a crucial role by suppressing the rate of gas-phase migration, enhancing dissolution trapping efficiency, and inducing reverse imbibition of formation water during the post-injection stage, thereby promoting greater retention of CO₂ in pore spaces in the form of residual gas and effectively increasing the proportion of residual trapping. Comprehensive analysis demonstrates that the storage behavior of impure CO₂ in saline aquifers is jointly governed by impurity properties, trapping mechanisms, and capillary pressure effects. The findings provide scientific support for optimizing injection strategies in impure CO₂ geological storage projects and offer important guidance for ensuring long-term storage security and improving storage efficiency.

Key words: saline aquifer storage, impure CO₂, migration behavior, occurrence forms, numerical simulation

摘要：

二氧化碳地质封存(GCS)是实现“双碳”战略目标的重要技术途径之一。由于工业源CO₂通常含有多种杂质气体，其提纯成本高，操作难度大，在实际工程中往往将杂质气体与CO₂共同注入地下。基于某CCS示范工程区石千峰组储层地质特征，构建二维地质模型，采用CMG-GEM组分模拟器开展非纯净CO₂的反应运移模拟。选取N₂和H₂S作为典型杂质组分，模拟非纯净CO₂在咸水层中的运移路径、赋存形态及其空间分布特征，系统分析结构封存、残余气封存和溶解封存在不同阶段对CO₂封存行为的主导性变化，探讨毛细管压力在非纯净CO₂地质封存过程中的作用。模拟结果表明，注入初期CO₂主要以超临界态聚集于储层顶部，随后束缚态和溶解态CO₂比例增加，封存稳定性与安全性显著提升；CO₂运移过程呈现明显的时空分异特征，注入气体在浮力驱动下迅速上升并聚集于盖层底部，随后在密度差和浓度梯度驱动下缓慢回流，促进溶解扩散，停注后气体沿盖层底部径向扩散，形成最大扩散距离约650 m的“舌形”前缘；杂质组分运移行为差异明显，N₂因溶解度低聚集于气液相驱替前缘，CO₂和H₂S由于溶解度较高在近井区形成溶解富集区，最高溶解度分别达到1.4 mol/kg-H₂O和0.53 mol/kg-H₂O；毛细管压力通过抑制气相迁移速率增强溶解封存效率，在注入后期诱发地层水反向渗吸，促使更多CO₂以残余气形式滞留于孔隙中，有效提升残余气封存比例。综合分析表明，非纯净CO₂在咸水层中的封存行为受杂质特性、赋存形态及毛细管压力等因素共同影响。研究成果为非纯净CO₂地质封存工程的注入方案优化提供科学依据，对保障CO₂长期封存安全性与提升封存效率具有重要指导意义。

关键词: 咸水层地质封存, 非纯净CO₂, 运移行为, 赋存形态, 数值模拟

CLC Number:

TE822
X701

ZHU Shuyan, HOU Lei, ZHANG Shuyong, XU Zicong, LIU Qian. Simulation of migration behavior and occurrence forms of impure CO₂ in saline aquifer geological storage[J]. Petroleum Science Bulletin, 2026, 11(1): 288-301.

朱淑艳, 侯磊, 张书勇, 许子聪, 刘倩. 非纯净CO₂在咸水层地质封存中运移行为与赋存形态模拟研究[J]. 石油科学通报, 2026, 11(1): 288-301.

/ / Recommend / Download Citations

URL: https://sykxtb.cup.edu.cn/EN/10.3969/j.issn.2096-1693.2026.02.007

https://sykxtb.cup.edu.cn/EN/Y2026/V11/I1/288

Figures/Tables 20

Table 1 Effects of Possible Gas Impurities on CO₂ Geological Storage

杂质类型	对CO₂地质封存的主要影响	参考文献
H₂S和N₂	(1)H₂S和N₂这类杂质气体对注入流体密度的影响会直接影响到地层中气相分布和运移规律。 (2)在储层埋深较浅的环境下，低浓度H₂S对于气相迁移速度的影响可近似忽略，相同浓度的N₂则会使气相迁移速度增长25%以上；而在储层埋深较深的环境下，气相迁移速度降低至4%，地层埋深的增加显著提高了N₂导致气态CO₂泄漏风险的安全性。	Yu[30]
CH₄	CH₄与N₂的作用类似	Barrufet[31]
CO	杂质CO由于其高还原性很容易被氧化成CO₂，杂质H₂也具有还原性但无毒性或腐蚀性，因此CO和H₂即使与围岩矿物等发应也不会导致矿物溶解或沉淀，其对二氧化碳地质封存的化学影响远不如SO_x、NO_x或H₂S等杂质重要。	Yu[30]
H₂		Yu[30]

Fig. 1 Conceptual model of reservoir-caprock assemblage

Fig. 2 Geological model (color scale indicates reservoir depth from the surface)

Table 2 Injection well locations and relevant parameter settings

参数	数值
注入井位置	(1，1，45-49)
注入井半径/m	0.5
注入流体	90%CO₂+5%H₂S+5%N₂
注入速率/(m³·d^-1)	8000
注入时间/a	20
总模拟时间/a	200

Table 3 Physical properties of fluid components

流体性质	CO₂	N₂	H₂S
临界压力P_c/MPa	7.38	3.39	8.94
临界温度T_c/℃	31.1	-146.9	100.05
临界体积V_c/(m³·kmol^-1)	0.094	0.0892	0.0985
分子量M_W/(g·mol^-1)	44.01	28.01	34.08
偏心因子	0.225	0.0377	0.109
气相在水相中的扩散系数/(m²·s^-1)	0.000 04	0.000 055	0.000 035

Fig. 3 Gas-water relative permeability curves and capillary pressure curve(Based on reference^[32])

Table 4 Hydrogeological parameters and model parameter settings

参数	取值
初始地层压力/MPa	18.9
初始储层温度/℃	65
水平渗透率/mD	6.58
渗透率各向异性比K_v/K_h	1
孔隙度	0.129
孔隙压缩系数/Pa^-1	4.5×10^-10
岩石颗粒密度/(kg·m^-3)	2600
岩石颗粒比焓/(J·kg^-1·℃^-1)	920
注入速率/(m³·d^-1)	8000
盐度	0.03

Fig. 4 Dynamic evolution of CO₂ occurrence forms during the entire simulation period

Fig. 5 Pressure distribution in the reservoir in different time intervals

Fig. 6 Temporal evolution characteristics of gas phase saturation

Fig. 7 Mole fraction of CO₂ in the gas phase in different time periods

Fig. 8 Mole fraction of H₂S in the gas phase in different time periods

Fig. 9 Mole fraction of N₂ in the gas phase in different time periods

Fig. 10 Mole fraction of CO₂ in the aqueous phase in different time intervals

Fig. 11 Mole fraction of H₂S in the aqueous phase in different time intervals

Fig. 12 Mole fraction of N₂ in the aqueous phase in different time intervals

Fig. 13 Pressure variation in perforated zones with/without capillary pressure effects in different time intervals

Fig. 14 Gas phase saturation variation with/without capillary pressure effects in different time intervals

Fig. 15 Variation of gas component dissolution in aqueous phase with/without capillary pressure effects

Fig. 16 Effect of capillary pressure on the storage amount of CO₂ in different phases

References 35

[1]	ALI M, JHA N K, PAL N, et al. Recent advances in carbon dioxide geological storage, experimental procedures, influencing parameters, and future outlook[J]. Earth-Science Reviews, 2022, 225: 103895. doi: 10.1016/j.earscirev.2021.103895 URL
[2]	QIN J, ZHONG Q, TANG Y, et al. CO₂ storage potential assessment of offshore saline aquifers in China[J]. Fuel, 2023, 341: 127681. doi: 10.1016/j.fuel.2023.127681 URL
[3]	ZHU E, QI Q, SHA M. Identify the effects of urbanization on carbon emissions(EUCE): a global scientometric visualization analysis from 1992 to 2018[J]. Environmental Science and Pollution Research, 2021, 28(24): 31358-31369. doi: 10.1007/s11356-021-12858-1
[4]	BENSON S M, COLE D R. CO₂ sequestration in deep sedimentary formations[J]. Elements, 2008, 4(5): 325-331. doi: 10.2113/gselements.4.5.325 URL
[5]	赵改善. 二氧化碳地质封存地球物理监测: 现状、挑战与未来发展[J]. 石油物探, 2023, 62(02): 194-211.
	[ZHAO G S. Geophysical monitoring for geological carbon sequestration: present status, challenges, and future development[J]. Geophysical Prospecting for Petroleum, 2023, 62(02): 194-211.]
[6]	CAO C, HOU Z, LI Z, et al. Numerical modeling for CO₂ storage with impurities associated with enhanced gas recovery in depleted gas reservoirs[J]. Journal of Natural Gas Science and Engineering, 2022, 102: 104554. doi: 10.1016/j.jngse.2022.104554 URL
[7]	FEATHER B, ARCHER R A. Enhanced natural gas recovery by carbon dioxide injection for storage purposes[C]// 17th Australia Fluid Mechanics Conference held in Auckland, New Zealand. 2010: 1-4.
[8]	NDLOVU P, BABAEE S, NAIDOO P. Review on CH₄-CO₂ replacement for CO₂ sequestration and CH₄/CO₂ hydrate formation in porous media[J]. Fuel, 2022, 320: 123795. doi: 10.1016/j.fuel.2022.123795 URL
[9]	LU P, LIU W, GAO C, et al. Evaluation of carbon dioxide storage in the deep saline layer of the Ordovician Majiagou Formation in the Ordos Basin[C]// IOP conference series: earth and environmental science. IOP Publishing, 2021, 675(1): 012058.
[10]	廖志伟, 羊俊敏, 钟翔宇, 等. 二氧化碳地质封存技术研究进展综述[J]. 地下空间与工程学报, 2024, 20(S1): 497-507. doi: 10.20174/j.JUSE.2024.S1.58
	[LIAO Z W, YANG J M, ZHONG X Y, et al. Review on research progress of carbon dioxide geological sequestration technology[J]. Chinese Journal of Underground Space and Engineering, 2024, 20(S1): 497-507 ] doi: 10.20174/j.JUSE.2024.S1.58
[11]	LI D, JIANG X. Numerical investigation of convective mixing in impure CO₂ geological storage into deep saline aquifers[J]. International Journal of Greenhouse Gas Control, 2020, 96: 103015. doi: 10.1016/j.ijggc.2020.103015 URL
[12]	LI D, JIANG X. Numerical investigation of the partitioning phenomenon of carbon dioxide and multiple impurities in deep saline aquifers[J]. Applied energy, 2017, 185: 1411-1423. doi: 10.1016/j.apenergy.2015.12.113 URL
[13]	MAHMOODPOUR S, ROSTAMI B, EMAMI-MEYBODI H. Onset of convection controlled by N₂ impurity during CO₂ storage in saline aquifers[J]. International Journal of Greenhouse Gas Control, 2018, 79: 234-247. doi: 10.1016/j.ijggc.2018.10.012 URL
[14]	PARK Y C, SHINN Y J, LEE H K, et al. Assessing CO₂ storage capacity of a steeply dipping, fault bounded aquifer and effect of impurity in CO₂ stream[J]. Energy Procedia, 2017, 114: 4735-4740. doi: 10.1016/j.egypro.2017.03.1611 URL
[15]	LI D, JIANG X, MENG Q, et al. Numerical analyses of the effects of nitrogen on the dissolution trapping mechanism of carbon dioxide geological storage[J]. Computers & Fluids, 2015, 114: 1-11. doi: 10.1016/j.compfluid.2015.02.014 URL
[16]	REZK M G, IBRAHIM A F, ADEBAYO A R. Influence of impurities on reactive transport of CO₂ during geo-sequestration in saline aquifers[J]. Fuel, 2023, 344: 127994. doi: 10.1016/j.fuel.2023.127994 URL
[17]	马馨蕊, 梁杰, 李清, 等. 咸水层CO₂地质封存研究进展及前景展望[J]. 海洋地质前沿, 2024, 40(10): 1-18.
	[MA X R, LIANG J, LI Q, et al. Progress and prospects of CO₂geological storage in saline aquifer[J]. Marine Geology Frontiers, 2024, 40(10): 1-18.]
[18]	LIU Y, HOU M, NING H, et al. Phase equilibria of CO₂+N₂+H₂O and N₂+CO₂+H₂O+NaCl+KCl+CaCl₂ systems at different temperatures and pressures[J]. Journal of Chemical & Engineering Data, 2012, 57(7): 1928-1932. doi: 10.1021/je3000958 URL
[19]	KOU Z, WANG H, BAGDONAS D, et al. Impact of sub-core scale heterogeneity on CO₂/brine multiphase flow for geological carbon storage in the Minnelusa sandstone[R]. Center for Economic Geology Research/University of Wyoming, 2020.
[20]	WANG H, ALVARADO V, SMITH E R, et al. Link Between CO₂‐Induced Wettability and Pore Architecture Alteration[J]. Geophysical Research Letters, 2020, 47(18): e2020GL088490.
[21]	WANG H, KOU Z, JI Z, et al. Investigation of enhanced CO₂ storage in deep saline aquifers by WAG and brine extraction in the Minnelusa sandstone, Wyoming[J]. Energy, 2022, 265: 126379. doi: 10.1016/j.energy.2022.126379 URL
[22]	JU L, SHAN B, GUO Z. Pore-scale study of convective mixing process in brine sequestration of impure CO₂[J]. Physical Review Fluids, 2022, 7(11): 114501. doi: 10.1103/PhysRevFluids.7.114501 URL
[23]	WEI N, LI X, WANG Y, et al. Geochemical impact of aquifer storage for impure CO₂ containing O₂ and N₂: Tongliao field experiment[J]. Applied energy, 2015, 145: 198-210. doi: 10.1016/j.apenergy.2015.01.017 URL
[24]	OMRANI S, GHASEMI M, MAHMOODPOUR S, et al. Insights from molecular dynamics on CO₂ diffusion coefficient in saline water over a wide range of temperatures, pressures, and salinity: CO₂ geological storage implications[J]. Journal of Molecular Liquids, 2021, 345: 117868. doi: 10.1016/j.molliq.2021.117868 URL
[25]	LI D, JIANG X. A numerical study of the impurity effects of nitrogen and sulfur dioxide on the solubility trapping of carbon dioxide geological storage[J]. Applied Energy, 2014, 128: 60-74. doi: 10.1016/j.apenergy.2014.04.051 URL
[26]	PAFFENHOLZ J. Introduction to this special section: The role of advanced modeling in enhanced carbon storage[J]. The Leading Edge, 2021, 40(6): 408-412. doi: 10.1190/tle40060408.1 URL
[27]	MENG C, FEHLER M. The role of geomechanical modeling in the measurement and understanding of geophysical data collected during carbon sequestration[J]. The Leading Edge, 2021, 40(6): 413-417. doi: 10.1190/tle40060413.1 URL
[28]	VERLIAC M, LE C J. Microseismic monitoring for reliable CO₂ injection and storage-Geophysical modeling challenges and opportunities[J]. The Leading Edge, 2021, 40(6): 418-423. doi: 10.1190/tle40060418.1 URL
[29]	WANG H, ALVARADO V, BAGDONAS D A, et al. Effect of CO₂-brine-rock reactions on pore architecture and permeability in dolostone: Implications for CO₂ storage and EOR[J]. International Journal of Greenhouse Gas Control, 2021, 107: 103283. doi: 10.1016/j.ijggc.2021.103283 URL
[30]	YU Y, LI Y, CHENG F, et al. Effects of impurities H₂S and N₂ on CO₂ migration and dissolution in sedimentary geothermal reservoirs, Journal of Hydrology, 2021, 603(B): 0022-1694.
[31]	BARRUFET M A, BACQUET A, FALCONE G. Analysis of the Storage Capacity for CO₂ Sequestration of a Depleted Gas Condensate Reservoir and a Saline Aquifer[J]. Journal of Canadian Petroleum Technology, 2010, 49(8): 23-31.
[32]	KOU Z, XIN Y, WANG H, et al. Exploring CO₂ storage with impurities in deep saline aquifers through computational experiments[J]. Renewable Energy, 2024, 223120085.
[33]	万玉玉. 鄂尔多斯盆地石千峰组咸水层CO₂地质储存中CO₂的迁移转化特征[D]. 长春: 吉林大学, 2012.
	[WAN Y Y. Migration and Transformation of CO₂ in CO₂ Geological Sequestration Process of Shiqianfeng Saline Aquifers in Orods Basin[D]. Changchun: Jilin University, 2012.]
[34]	喻英. 非纯净CO₂地质封存中CO₂-N₂-O₂的运移规律研究[D]. 武汉: 中国地质大学, 2018.
	[YU Y. Transport modelling of impure CO₂ with N₂ and O₂ for geological storage: A case study of the Ordos Basin[D]. Wuhan: China University of Geosciences, 2018.]
[35]	LEI H, LI J, LI X, et al. Numerical modeling of co-injection of N₂ and O₂ with CO₂ into aquifers at the Tongliao CCS site[J]. International Journal of Greenhouse Gas Control, 2016, 54: 228-241. doi: 10.1016/j.ijggc.2016.09.010 URL

Please choose a citation manager

Content to export

Simulation of migration behavior and occurrence forms of impure CO₂ in saline aquifer geological storage

非纯净CO₂在咸水层地质封存中运移行为与赋存形态模拟研究

RichHTML

PDF

Knowledge

Cited

Abstract

Cite this article

share this article

Figures/Tables 20

References 35

Related Articles 11

Recommended Articles

Metrics

Comments

[1]	LI Yaobin, XU Tianfu, XIN Xin, YUAN Yilong, ZHU Huixing. Numerical simulation of natural gas hydrate production: Theories, technologies, and applications [J]. Petroleum Science Bulletin, 2026, 11(1): 257-275.
[2]	WANG Xinwei, XIANG Pengfei, ZHOU Luming, ZHAO Zhihong, LIU Jian, WANG Tinghao, HE Jie, LU Xingchen, REN Xiaoqing, MA Zining. Numerical simulation study on seepage-heat transfer characteristics and well pattern optimization of geothermal fields under multi-well production and reinjection conditions [J]. Petroleum Science Bulletin, 2026, 11(1): 276-287.
[3]	GE Chenqi, LEI Zhengdong, JI Dongqi, ZHANG Yuan, LIU Yishan, YAN Yiqun, HUI Gang, CHEN Zhangxing. Feasibility of gas displacement application between horizontal wells in shale oil [J]. Petroleum Science Bulletin, 2026, 11(1): 239-256.
[4]	XIONG Chao, HE Senlin, HUANG Zhongwei, SHI Huaizhong, FENG Xiao, YANG Zixuan. Optimization of rock-breaking parameters under the combined intrusion and cutting action of Stinger PDC cutter [J]. Petroleum Science Bulletin, 2025, 10(6): 1267-1278.
[5]	GAO Budong, MOU Jianye, ZHANG Shicheng, MA Xinfang, LU Panpan, WANG Lei. Modeling of multi-stage alternating injection acid fracturing based on the VOF interface tracking method [J]. Petroleum Science Bulletin, 2025, 10(3): 540-552.
[6]	LIU Changni, WU Shenghe, XU Zhenhua, YUE Dali, WANG Wurong, CHEN Yakun, SUN Yide, CUI Wenfu, LI Keli. Architectural characteristics of shallow water delta-offshore beach-bar system in lacustrine basin: Taking the Shahejie Formation of Shengtuo Oilfield, Dongying Sag as an example [J]. Petroleum Science Bulletin, 2025, 10(3): 430-445.
[7]	YANG Liu;ZHAO Ziheng;ZHANG Jigang;HAN Yunhao;LI Mingjun;LIU Zhen;JIN Yun;YAN Chuanliang. Spontaneous imbibition laws of fracture-containing porous media based on phase field theory [J]. , 2025, 10(2): 269-282.
[8]	XU Xitong;LAI Fengpeng;WANG Ning;MIAO Lili;ZHAO Qianhui. Numerical simulation of the dynamic imbibition laws of shale oil influ-enced by multiple factors [J]. , 2025, 10(2): 232-244.
[9]	ZHANG Jingru;YAN Wei;WANG Jianbo;LIU Lingtong;JIANG Qingping;FENG Yongcun. The influence of gravel grading parameters on the mechanical proper-ties and crack propagation of conglomerate [J]. , 2024, 9(5): 798-807.
[10]	GAN Quan;LIU Yanting;MA Yueqiang;WANG Tao;HU Dawei;ZHI Sheng. Influence of permeability anisotropy on high-efficiency energy storage power generation system of geothermal battery [J]. , 2024, 9(3): 476-486.
[11]	CHEN Huan;YU Jifei;CAO Yanfeng;DU Xiaoyou;YAN Xinjiang;AI Chuanzhi. Application and research into dilatation and injection enhancement technology for unconsolidated sandstone injectors in an offshore oilfield [J]. , 2023, 8(5): 649-659.

模态框（Modal）标题

Please choose a citation manager

Content to export