Molecular simulation of wettability of water-methane-carbon dioxide-carbon system

doi:10.3969/j.issn.1006-6535.2025.02.011

Abstract

Abstract: To address the difficulty in conducting wettability studies at the molecular scale,molecular simulation methods were employed to investigate the wettability behavior of droplets in shale nanopores after interaction with the methane-carbon dioxide-carbon system (wettability was characterized by surface tension and contact angle).The results show that the proportion of CO₂ molecules, X_CO₂,significantly affects the surface tension γ of the CH₄-CO₂-H₂O system.The surface tension γ decreases with increasing temperature and X_CO₂,with a maximum reduction of approximately 40%.Further analysis revealed the variation of droplet contact angle with changes in CH₄ and CO₂ pressure.It was found that in a CH₄ environment,when the pressure exceeds 78 MPa,the droplet detaches from the solid surface,forming a contact angle of 180°,indicating that the shale pore surface reaches a completely hydrophobic state. In a CO₂ environment,the corresponding pressure for the shale surface to become completely hydrophobic is 12 MPa.The simulation results are consistent with relevant experimental data. Compared to CH₄, CO₂ exhibits stronger interaction with the shale surface, thereby displacing CH₄ attached to the solid surface and enhancing gas recovery.For CH₄-CO₂ mixtures, the contact angle shows a linear positive correlation with the proportion of CO₂ molecules.The research findings provide theoretical guidance on the relationship between wettability and enhanced recovery in shale.

Key words: water-methane-carbon dioxide-carbon system, wettability, contact angle, molecular modeling, enhanced recovery, shale

CLC Number:

TE349

YONG Wei, WEI Zhijie, LIU Yuyang, WANG Deqiang, CUI Yongzheng, ZHANG Jian, ZHOU Wensheng. Molecular simulation of wettability of water-methane-carbon dioxide-carbon system[J]. Special Oil & Gas Reservoirs, 2025, 32(2): 89-94.

References

[1] 霍旭,孙灵辉,李博文,等.页岩储层润湿性的影响因素及研究进展[J].应用化工,2023,52(12):3354-3358.
HUO Xu,SUN Linghui,LI Bowen,et al.Influencing factors and research progress of shale reservoir wettability[J].Applied Chemical Industry,2023,52(12):3354-3358.
[2] 刘杰,陈银,章涛,等.页岩纳米有机质孔隙中的润湿性研究[J].力学学报,2023,55(8):1800-1808.
LIU Jie,CHEN Yin,ZHANG Tao,et al.Wettability analysis in shale organic pores at the nanoscale[J].Chinese Journal of Theoretical and Applied Mechanics,2023,55(8):1800-1808.
[3] 端祥刚,高树生,胡志明,等.页岩微纳米孔隙多尺度渗流理论研究进展[J].特种油气藏,2017,24(5):1-9.
DUAN Xianggang,GAO Shusheng,HU Zhiming,et al.Research progress in multi-scale percolation theory in shale micro-nano pores[J].Special Oil & Gas Reservoirs,2017,24(5):1-9.
[4] 胡志明,端祥刚,常进,等.页岩气与煤层气开发特征模拟实验研究[J].特种油气藏,2019,26(4):126-130.
HU Zhiming,DUAN Xianggang,CHANG Jin,et al.Physical simulation of shale gas and coalbed gas development[J].Special Oil & Gas Reservoirs,2019,26(4):126-130.
[5] PAN B,LI Y,WANG H,et al.CO₂ and CH₄ wettabilities of organic-rich shale[J].Energy Fuels,2018,32(2):1914-1922.
[6] ZHOU Y F,HATZIGNATIOU D G,HELLAND J O,et al.Computation of three-phase capillary pressure curves and fluid configurations at mixed-wet conditions in 2D rock images[J].SPE Journal,2016,21(1):152-169.
[7] 曹成,李宇,张烈辉,等.润湿性对CO₂溶解封存的影响机制与调控方法研究进展[J].天然气工业,2024,44(12):162-175.
CAO Cheng,LI Yu,ZHANG Liehui,et al.Research progress on influence mechanism and control method of wettability on CO₂ dissolution storage[J].Natural Gas Industry,2024,44(12):162-175.
[8] 张成龙,钱战宏,张建东,等.湖南桑植地区下志留统龙马溪组页岩孔缝特征及主控因素[J].大庆石油地质与开发,2023,42(2):13-21.
ZHANG Chenglong,QIAN Zhanhong,ZHANG Jiandong,et al.Pore and fracture characteristics and main controlling factors of Lower Silurian Longmaxi Formation shale in Sangzhi Area of Hunan Province[J].Petroleum Geology & Oilfield Development in Daqing,2023,42(2):13-21.
[9] 李楠,洪海涛,赵正望,等.川东地区侏罗系大安寨段页岩储层特征及发育控制因素[J].断块油气田,2024,31(2):187-196.
LI Nan,HONG Haitao,ZHAO Zhengwang,et al.Characteristics and development controlling factors of shale reservoirs of Jurassic Daanzhai Member in eastern Sichuan Basin [J].Fault-Block Oil & Gas Field,2024,31(2):187-196.
[10] 张建中,高树生,熊伟,等.基于致密砂岩储层气水渗流阻力系数的产能新模型[J].天然气工业,2023,43(1):177-187.
ZHANG Jianzhong,GAO Shusheng,XIONG Wei,et al.A new productivity model based on gas-water seepage resistance coefficient for tight sandstone reservoirs[J].Natural Gas Industry,2023,43(1):177-187.
[11] 刘印华,杨英,马文涛,等.海陆过渡相页岩孔隙结构表征及页岩气渗流规律模拟[J].断块油气田,2024,31(2):207-215.
LIU Yinhua,YANG Ying,MA Wentao,et al.Pore structure characterization of marine-continental transitional shale and seepage law simulation of shale gas[J].Fault-Block Oil & Gas Field,2024,31(2):207-215.
[12] 陈江,高宇,陈沥,等.页岩油CO₂非混相吞吐与埋存实验及影响因素[J].大庆石油地质与开发,2023,42(2):143-151.
CHEN Jiang,GAO Yu,CHEN Li,et al. Experiment and influencing factors of CO₂ immiscible huff-and-puff and sequestration for shale oil[J].Petroleum Geology & Oilfield Development in Daqing,2023,42(2):143-151.
[13] 胡东风,魏志红,王威,等.四川盆地东北部雷页1井上二叠统大隆组页岩气勘探突破及其启示[J].天然气工业,2023,43(11):28-39.
HU Dongfeng,WEI Zhihong,WANG Wei,et al.Breakthrough of shale gas exploration in Dalong Formation of Upper Permian by Well Leiye 1 in the northeastern Sichuan Basin and its implications[J].Natural Gas Industry,2023,43(11):28-39.
[14] 程秋洋,杨洪志,游利军,等.页岩气层水-岩作用机理、特征及意义[J].油气地质与采收率,2024,31(6):96-108.
CHENG Qiuyang,YANG Hongzhi,YOU Lijun,et al.Mechanism,characteristic,and significance of water-rock interaction in shale gas reservoirs[J].Petroleum Geology and Recovery Efficiency,2024,31(6):96-108.
[15] 杨明,薛程伟,李朝阳,等.页岩油CO₂吞吐影响因素及微观孔隙动用特征[J].大庆石油地质与开发,2023,42(4):148-156.
YANG Ming,XUE Chengwei,LI Chaoyang,et al.Influencing factors of CO₂ huff and puff and micro-pores producingcharacteristics of shale oil[J].Petroleum Geology & Oilfield Development in Daqing,2023,42(4):148-156.
[16] 孙龙德,王小军,冯子辉,等.松辽盆地古龙页岩纳米孔缝形成机制与页岩油富集特征[J].石油与天然气地质,2023,44(6):1350-1365.
SUN Longde,WANG Xiaojun,FENG Zihui,et al.Formation mechanisms of nano-scale pores/fissures and shale oil enrichment characteristics for Gulong shale,Songliao Basin[J].Oil & Gas Geology,2023,44(6):1350-1365.
[17] HUDSON G H,MCCOUBREY J C.Intermolecular forces between unlike molecules:a more complete form of the combining rules[J].Trans.Faraday Soc,1960,56(1):761-766.
[18] SAITO R,MATSUO R,KIMURA T,et al.Anomalous potential barrier of double-wall carbon nanotube[J].Chemical Physics Letters,2001,348(3):187-193.
[19] WU Y,TEPPER H L,VOTH G A,et al.Flexible simple point-charge water model with improved liquid-state properties[J].The Journal of Chemical Physics,2006,124(2):1-12.
[20] AIMOLI C G,MAGINN E J,ABREU C R,et al.Transport properties of carbon dioxide and methane from molecular dynamics simulations[J].The Journal of Chemical Physics,2014,141(13):1-12.
[21] CYGAN R T,ROMANOV V N,MYSHAKIN E M,et al.Molecular simulation of carbon dioxide capture by montmorillonite using an accurate and flexible force field[J].The Journal of Physical Chemistry C,2012,116(24):13079-13091.
[22] STUART S J,TUTEIN A B,HARRISON J A,et al.A reactive potential for hydrocarbons with intermolecular interactions[J].The Journal of Chemical Physics,2000,112(14):6472-6486.
[23] PLIMPTON S.Fast parallel algorithms for short-range molecular dynamics[J].Journal of Computational Physics,1995,117(1):1-19.
[24] SWOPE W C,ANDERSEN H C,BERENS P H,et al.A computer simulation method for the calculation of equilibrium constants for the formation of physical clusters of molecules:application to small water clusters[J].The Journal of Chemical Physics,1982,76(1):637-649.
[25] REN Q,CHEN G,YAN W,et al.Interfacial tension of(CO₂+CH₄)plus water from 298 K to 373 K and pressures up to 30 MPa[J].Journal of Chemical and Engineering Data,2000,45(4):610.
[26] YANG Y,NARAYANAN NAIR A K,SUN S,et al.Molecular dynamics simulation study of carbon dioxide,methane,and their mixture in the presence of brine[J].The Journal of Physical Chemistry B,2017,121(41):9688-9698.
[27] KLEWIAH I,BERAWALA D S,ALEXANDER Walker H C,et al.Review of experimental sorption studies of CO₂ and CH₄ in shales[J].Journal of Natural Gas Science and Engineering,2020,73(1):1-15.