Abstract
CO(2) huff-and-puff demonstrates excellent injectivity and gas channeling resistance in tight reservoirs, yet aqueous phase invasion significantly diminishes its oil recovery efficiency. To investigate the mechanisms of aqueous phase impacts, CO(2) huff-and-puff experiments were conducted under varying water saturation levels, complemented by extended core displacement tests with different injection patterns. A triphilic surfactant, C(8)EO(3)PO(2)COOCH(3) (CEPC), was introduced to mitigate aqueous phase interference. Its performance in reducing interfacial tension (IFT) and enhancing CO(2) dissolution/diffusion was systematically evaluated. Optimal injection parameters were determined through 1D core experiments, followed by 2D planar flooding experiments to assess recovery enhancement mechanisms. Results reveal that aqueous phases impair CO(2) diffusion and sweep efficiency, weakening solution gas drive effects. Compared to anhydrous conditions, oil recovery decreased by 10.25%, 19.12%, and 26.03% at 5%, 10%, and 20% water saturation, respectively. CEPC reduced the CO(2)-water and CO(2)-oil IFT by 89.4% and 76.8%, respectively, while accelerating the CO(2) dissolution kinetics by 2.1-3.4 times at 50% water saturation. At 20% water saturation, the optimal concentration of CEPC is 0.5 wt %, while the optimal soaking pressure and soaking time for the CO(2) huff-and-puff are 20 MPa and 12 h, respectively. In 2D experiments, CEPC-assisted CO(2) huff-and-puff achieved 25.36% oil recovery, representing a 9.56% enhancement over conventional CO(2) injection. The synergy arises through two mechanisms: CEPC facilitates CO(2) breakthrough across aqueous phases to amplify dissolved gas drive by increasing CO(2)-oil contact and dissolution capacity, while simultaneously reducing capillary confinement of aqueous phases in micronano pores to alleviate water blockage and enhance sweep efficiency. These findings provide critical insights for optimizing the recovery of CO(2)-enhanced nanoparticles in water-bearing tight reservoirs.