Using fluid displacement in a Hele-Shaw cell, we experimentally demonstrate the arresting effect of an imposed flow on a phase separation occurring in a growing liquid-liquid interfacial region, unlike in an initially homogeneous single-phase mixture quenched within the miscibility gap. Increasing the imposed flow rate reduces the exponent α in the form $\mathrm{\Delta }A\propto t^{\alpha }$, where $\mathrm{\Delta }A$ is the increase in the area occupied by the displacing fluid owing to phase separation. We show that α can be expressed as a function of the ratio of the phase separation rate to the flow rate on a single curve, indicating that the competition between the imposed flow and phase separation rates determines the degree of the interfacial phase separation. The arresting effect and the mechanism are verified by a numerical simulation.

• Received 16 August 2022
• Accepted 5 January 2024

DOI:https://doi.org/10.1103/PhysRevFluids.9.024003