Abstract
The pore structure of caprock plays an important role in underground gas storage security, as it significantly influences the sealing capacity of caprock. However, the pore structure evolution of caprock with the cyclic stress perturbations triggered by the cyclic gas injection or extraction remains unclear. In this study, the pore structure changes of mudstone caprock under cyclic loading and unloading were obtained by the nuclear magnetic resonance (NMR) tests system, then the influence of the changes on the breakthrough pressure of caprock was discussed. The results indicated that the pore structure changes are depending on the stress loading-unloading path and stress level. In the first cyclic, at the loading stage, with the increase of confining stress, the NMR T2 spectrum curve moved to the left, the NMR signal amplitude of the first peak increased, while the amplitude of the second peak decreased gradually. This indicated that the larger pores of mudstone are compressed and transformed into smaller pores, then the number of macropores decreased and the number of micro- and mesopores increased. For a certain loading-unloading cycle, the porosity curve of mudstone in the loading process is not coincide with that in the unloading process, the porosity curve in the loading process was located below that in the unloading process, which indicated that the pore structure change is stress path dependent. With the increase of cycle numbers, the total porosity shown an increasing trend, indicating that the damage of mudstone occurred under the cyclic stress load-unload effects. With the increase of porosity, the breakthrough pressure of mudstone decreased with the increase of the cyclic numbers, which may increase the gas leakage risk. The results can provide significant implication for the underground gas storage security evaluation.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Astiaso Garcia D, Barbanera F, Cumo F, Di Matteo U, Nastasi B (2016). Expert opinion analysis on renewable hydrogen storage systems potential in Europe. Energies, 9(11): 963
Carneiro J F, Matos C R, van Gessel S (2019). Opportunities for large scale energy storage in geological formations in mainland Portugal. Renew Sustain Energy Rev, 99: 201–211
Chao Z, Wang H, Xu W, Ji H, Zhao K (2017). Study on the evolution of permeability and porosity of columnar joint materials under cyclic loading and unloading. Chinese J Rock Mech Eng, 36(1): 124–141 (in Chinese)
Cheng L, Li D, Wang W, Liu J (2021). Heterogeneous transport of free ch4 and free CO2 in dual-porosity media controlled by anisotropic in situ stress during shale gas production by CO2 flooding: implications for CO2 geological storage and utilization. ACS Omega, 6(40): 26756–26765
Chu Z, Wu Z, Liu Q, Weng L, Wang Z, Zhou Y (2021). Evaluating the microstructure evolution behaviors of saturated sandstone using NMR testing under uniaxial short-term and creep compression. Rock Mech Rock Eng, 54(9): 4905–4927
Cui X, Bustin R M (2005). Volumetric strain associated with methane desorption and its impact on coalbed gas production from deep coal seams. AAPG Bull, 89(9): 1181–1202
Fan C, Wen H, Li S, Bai G, Zhou L (2022). Coal seam gas extraction by integrated drillings and punchings from the floor roadway considering hydraulic-mechanical coupling effect. Geofluids, 2022: 1–10
Gao H, Li H A (2016). Pore structure characterization, permeability evaluation and enhanced gas recovery techniques of tight gas sandstones. J Nat Gas Sci Eng, 28: 536–547
Hildenbrand A, Schlömer S, Krooss B M, Littke R (2004). Gas breakthrough experiments on pelitic rocks: comparative study with N2, CO2 and CH4. Geofluids, 4(1): 61–80
Hu J, Dong Z, Ma S, Qin X, Xiao X, Zhuan D (2021). Seepage characteristics of damaged rock under stress-seepage coupling. Gold Sci Tech, 29(3): 355–363
Jayasekara D W, Ranjith P G, Wanniarachchi W, Rathnaweera T D (2020). Understanding the chemico-mineralogical changes of caprock sealing in deep saline CO2 sequestration environments: a review study. J Supercrit Fluid, 161: 104819
Jiang J, Yang W, Cheng Y, Zhao K, Zheng S (2019). Pore structure characterization of coal particles via MIP, N2 and CO2 adsorption: effect of coalification on nanopores evolution. Powder Technol, 354: 136–148
Kawaura K, Akaku K, Nakano M, Ito D, Takahashi T, Kiriakehata S (2013). Examination of methods to measure capillary threshold pressures of pelitic rock samples. Energy Procedia, 37: 5411–5418
Lv X, Wang Y, Yu H, Bai Z (2017). Major factors affecting the closure of marine carbonate caprock and their quantitative evaluation: a case study of Ordovician rocks on the northern slope of the Tazhong uplift in the Tarim Basin, western China. Ma Pet Geol, 83: 231–245
Lei R, Wang Y, Zhang L, Liu B, Long K, Luo P, Wang Y K (2019). The evolution of sandstone microstructure and mechanical properties with thermal damage. Energy Sci Eng, 7(6): 3058–3075
Li H, Yang D, Zhong Z, Sheng Y, Liu X (2018b). Experimental investigation on the micro damage evolution of chemical corroded limestone subjected to cyclic loads. Int J Fatigue, 113: 23–32
Li J, Zhou K, Liu W, Deng H (2016). NMR research on deterioration characteristics of microscopic structure of sandstones in freeze–thaw cycles. Trans Nonferrous Met Soc China, 26(11): 2997–3003
Li X, Kang Y, Haghighi M (2018a). Investigation of pore size distributions of coals with different structures by nuclear magnetic resonance (NMR) and mercury intrusion porosimetry (MIP). Measurement, 116: 122–128
Liu J, Xie L Z, He B, Gan Q, Zhao P (2021). Influence of anisotropic and heterogeneous permeability coupled with in-situ stress on CO2 sequestration with simultaneous enhanced gas recovery in shale: quantitative modeling and case study. Int J Greenh Gas Control, 104:103208
Ma X, Yu B, Ma D, Zhang S, Cheng Y, Wang K, Yang Y (2010). Project design and matching technologies for underground gas storage based on a depleted sandstone gas reservoir. Nat Gas Ind, 30(8): 67–71
Matos C R, Carneiro J F, Silva P P (2019). Overview of large-scale underground energy storage technologies for integration of renewable energies and criteria for reservoir identification. J Energy Storage, 21: 241–258
Paluszny A, Graham C C, Daniels K A, Tsaparli V, Xenias D, Salimzadeh S, Whitmarsh L, Harrington J F, Zimmerman R W (2020). Caprock integrity and public perception studies of carbon storage in depleted hydrocarbon reservoirs. Int J Greenh Gas Control, 98: 103057
Pang J, Qian G, Wang B, Yang Z, Wei Y, Li Y (2012). Evaluation of sealing ability of underground gas storage converted from the Xinjiang H Gas Field. Nat Gas Ind, 32(2): 83–85
Parra D, Valverde L, Pino F J, Patel M K (2019). A review on the role, cost, and value of hydrogen energy systems for deep decarbonization. Renew Sustain Energy Rev, 101: 279–294
Schmitt M, Poffo C M, De Lima J C, Fernandes C P, Dos Santos V S S (2017). Application of photoacoustic spectroscopy to characterize thermal diffusivity and porosity of caprocks. Eng Geol, 220: 183–195
Shukla R, Ranjith P, Haque A, Choi X (2010). A review of studies on CO2 sequestration and caprock integrity. Fuel, 89(10): 2651–2664
Sing K S W (1985). Reporting physisorption data for gas/solid systems with special reference to the determination of surface area and porosity. Pure Appl Chem, 57(4): 603–619
Takeda M, Manaka M (2018). Effects of confining stress on the semipermeability of siliceous mudstones: implications for identifying geologic membrane behaviors of argillaceous formations. Geophys Res Lett, 45(11): 5427–5435
Tang Y, Long K, Wang J, Xu H, Wang Y, He Y, Shi L, Zhu H (2021). Change of phase state during multi-cycle injection and production process of condensate gas reservoir based underground gas storage. Pet Explor Dev, 48(2): 395–406
Tarkowski R (2019). Underground hydrogen storage: characteristics and prospects. Renew Sustain Energy Rev, 105: 86–94
Wang G, Han D, Qin X, Liu Z, Liu J (2020). A comprehensive method for studying pore structure and seepage characteristics of coal mass based on 3D CT reconstruction and NMR. Fuel, 281: 118735
Wang L, Zhao N, Sima L, Meng F, Guo Y (2018). Pore structure characterization of the tight reservoir: systematic integration of mercury injection and nuclear magnetic resonance. Energy Fuels, 32(7): 7471–7484
Wang X L, Economides M J (2012). Purposefully built underground natural gas storage. J Nat Gas Sci Eng, 9: 130–137
Wang Z, Cui H, Wei G, Jia T, Guo J, He X (2021). Study on the quantitative characterization and seepage evolution characteristics of pores of loaded coal based on NMR. ACS Omega, 6(43): 28983–28991
Wu T, Pan Z, Connell L D, Liu B, Fu X, Xue Z (2020). Gas breakthrough pressure of tight rocks: a review of experimental methods and data. J Nat Gas Sci Eng, 81: 103408
Xu J, Xian X, Wang H, Wang W, Yang X (2006). Experimental study on rock deformation characteristics under cycling loading and unloading conditions. Chinese J Rock Mech Eng, 25(1): 3040–3045 (in Chinese)
Xu L, Li Q, Myers M, Chen Q, Li X (2019). Application of nuclear magnetic resonance technology to carbon capture, utilization and storage: a review. J Rock Mech Geotech Eng, 11(4): 892–908
Xu T, Tian H, Zhu H, Cai J (2022). China actively promotes: CO2 capture, utilization and storage research to achieve carbon peak and carbon neutrality. Adv Geo-Energy Res, 6(1): 1–3
Yao Y, Liu D, Che Y, Tang D, Tang S, Huang W (2010). Petrophysical characterization of coals by low-field nuclear magnetic resonance (NMR). Fuel, 89(7): 1371–1380
Zhai C, Qin L, Liu S, Xu J, Tang Z, Wu S (2016). Pore structure in coal: pore evolution after cryogenic freezing with cyclic liquid nitrogen injection and its implication on coalbed methane extraction. Energy Fuels, 30(7): 6009–6020
Zhang C, Wang M (2022). A critical review of breakthrough pressure for tight rocks and relevant factors. J Nat Gas Sci Eng, 100: 104456
Zhang F, Jiang Z, Sun W, Li Y, Zhang X, Zhu L, Wen M (2019a). A multiscale comprehensive study on pore structure of tight sandstone reservoir realized by nuclear magnetic resonance, high pressure mercury injection and constant-rate mercury injection penetration test. Mar Pet Geol, 109: 208–222
Zhang L, Wang Y, Miao X, Gan M, Li X (2019c). Geochemistry in geologic-CO2 utilization and storage: a brief review. Adv Geo-Energy Res, 3(3): 304–313
Zhang W, Ning Z, Gai S, Zhu J, Fan F, Liu Z, Wang H (2022). Fast and effective observations of the pore structure of tight sandstones at the same location by utilizing AFM and CF-SEM. J Petrol Sci Eng, 208: 109554
Zhang Z, Yu X, Deng M (2019b). Damage evolution of sandy mudstone mechanical properties under mining unloading conditions in gob-side entry retaining. Geotech Geol Eng, 37(4): 3535–3545
Zhao P, He B, Zhang B, Liu J (2022). Porosity of gas shale: is the NMR-based measurement reliable? Petrol Sci, 19(2): 509–517
Zheng S, Yao Y, Elsworth D, Wang B, Liu Y (2020). A novel pore size classification method of coals: investigation based on NMR relaxation. J Nat Gas Sci Eng, 81: 103466
Zhou X, Lu X, Quan H, Qian W, Mu X, Chen K, Wang Z, Bai Z (2019). Influence factors and an evaluation method about breakthrough pressure of carbonate rocks: an experimental study on the Ordovician of carbonate rock from the Kalpin area, Tarim Basin, China. Mar Pet Geol, 104: 313–330
Acknowledgments
This study was financially supported by the National Natural Science Foundation of China (Grant No. 52174107), the Basic Research and Frontier Exploration Projects in Chongqing (No. cstc2021 yszx-jcyjX0010).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Sun, J., Dong, Z., Zhu, S. et al. Pore structure evolution of mudstone caprock under cyclic load-unload and its influence on breakthrough pressure. Front. Earth Sci. 17, 691–700 (2023). https://doi.org/10.1007/s11707-022-1019-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11707-022-1019-9