“It has long been pointed out that viscous fingering in partially miscible fluids occurs in underground processes with high-pressure conditions, such as oil recovery and CO ₂ storage.  However, such viscous fingering has been theoretically studied in the last few years,” said Dr. Nagatsu, one of the corresponding authors on the paper and Associate Professor in the Department of Chemical Engineering at Tokyo University of Agriculture and Technology (TUAT). “Experimental studies of such VF have not been done at all. One of the reasons is that fluid mechanics researchers did not use experimental conditions that were partially miscible at room temperature and atmospheric pressure.”

The research team succeeded in changing the miscibility of the system to fully miscible, immiscible, and partially miscible with little change in the viscosities at room temperature and atmospheric pressure. They used an aqueous two-phase system consisting of polyethylene-glycol (PEG), sodium-sulfate (Na ₂ SO ₄ ), and water (see Figure), which were described in the same research team’s paper published in 2019. Here, in the partially miscible system, a pure PEG solution and a pure Na ₂ SO ₄ solution dissolve each other with finite solubility, and as a result, the phase is separated into a PEG-rich phase (phase L) and a Na ₂ SO ₄ -rich phase (phase H) (see Figure).

They have carried out experiments by using this solution system in which a less-viscous liquid displaces a more-viscous one in a Hele-Shaw cell (see Figure) which is a model mimics flow in porous media. “Our team found that topological change is observed in the case where the two liquids are partially miscible (see Figure and Movie). This is the first instance of topological change in viscous fingering although various changes in the pattern due to various physicochemical effects, so far, have been reported when the two fluids are fully miscible or immiscible. We clearly showed this topological change originates from a phase separation occurring between the two fluids and the spontaneous motion driven by it,” Nagatsu explains.

“Our result overturns the common understanding of more than 60 years in VF research which began in the 1950s that the characteristics of VF are divided into immiscible and fully miscible cases and it demonstrates the existence and importance of the partially miscible case, which becomes the third classification category. This will open a new cross-disciplinary research area involving hydrodynamics and chemical thermodynamics. Also, the displacement with partial miscibility in a porous medium takes places in the oil recovery process from the formation and the CO ₂ injection process into the formation. Thus, our finding is expected to create new control methodology of those processes by utilizing the partial miscibility,” adds Nagatsu.

Figure:  Topological change of viscous fingering pattern.
(top)Viscous fingering in Hele-Shaw cell which is a thin gap between two parallel plates. (bottom) Schematics of the fully miscible, immiscible and partially miscible interface and viscous fingering experimental results in each systems. Classical viscous fingering pattern for the fully miscible and immiscible systems is observed. Surprisingly, in the partially miscible systems, we observe a multiple droplet formation pattern: this is a new topological change of viscous fingering pattern.
(credit:  Yuichiro Nagatsu/TUAT, Takahiko Ban/ Osaka University, Manoranjan Mishra/IIT Ropar)

Movie: Temporal evolution of multiple droplet formation during VF experiment
(credit:  Yuichiro Nagatsu/TUAT, Takahiko Ban/ Osaka University, Manoranjan Mishra/IIT Ropar)

The article, “Phase separation effects on a partially miscible viscous fingering dynamics,” was published in Journal of Fluid Mechanics at DOI: https://doi.org/10.1017/jfm.2020.406 .

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