渗吸
纳米流体
油页岩
润湿
微模型
提高采收率
大孔隙
毛细管压力
吸附
接触角
页岩油
化学工程
表面张力
分离压力
材料科学
介孔材料
饱和(图论)
水银孔隙仪
毛细管作用
磁导率
纳米材料
多孔介质
复合材料
纳米流体学
纳米颗粒
作者
Zixuan Wang,M.L. Gao,Lianbao Yuan,Na Zhao,Liangfei Xiao,Hao Zheng,Yizheng Zhang,Yiming Zhang,Caili Dai
出处
期刊:Energy & Fuels
[American Chemical Society]
日期:2025-09-16
卷期号:39 (38): 18491-18502
被引量:2
标识
DOI:10.1021/acs.energyfuels.5c03641
摘要
Shale oil development faces challenges such as rapid production decline and high-cost formation damage caused by refracturing. To address these issues, this study proposes an active silica-based nanofluid with a total concentration of 0.12 wt % (0.045 wt % nanoparticles and 0.075 wt % AES surfactant). Dynamic light scattering (DLS) analysis demonstrates that the nanofluid exhibits excellent stability under high-temperature and high-salinity conditions (90 °C, salinity of 1.0 × 10 5 mg/L), maintaining an average hydrodynamic diameter of approximately 22 nm, which is significantly smaller than that of the unmodified system (30 nm). Interfacial tension (IFT) measurements revealed a stable IFT of 0.358 mN/m at a concentration of 0.3 wt %, while dynamic contact angle tests confirmed its strong wettability alteration capability. Spontaneous imbibition experiments revealed enhanced oil recovery, with increases of 23.8 and 10.62% compared to simulated formation water (SF water) and AES alone, respectively. Additionally, results indicated that higher core permeability facilitated easier oil–water extraction, while oil saturation primarily influenced oil–water displacement through the starting pressure gradient. A multiscale pore classification model was established by integrating nuclear magnetic resonance (NMR), mercury intrusion porosimetry (MIP), and nitrogen adsorption analysis, enabling the quantification of oil contributions from different pore size ranges: micropores (<0.07 μm) contributed 50.94%, macropores (>3.67 μm) 28.92%, and mesopores (0.07–3.67 μm) 20.15%. These results demonstrate its crucial role in overall oil recovery during shale imbibition. Finally, the mechanism behind enhanced recovery was elucidated through synergistic wettability alteration and capillary displacement equations. This work presents a cost-effective nanofluid formulation and a multiscale pore analysis methodology, providing practical approaches and theoretical insights for enhancing shale oil recovery.
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