Paper Number
IN28
Session
Flow-induced Instabilities in Non-Newtonian Fluids
Title
Elastic turbulence in structurally-heterogeneous porous media: Linking pore-scale flow behavior to macroscopic flow resistance
Presentation Date and Time
October 13, 2022 (Thursday) 10:35
Track / Room
Track 5 / Sheraton 2
Authors
- Browne, Christopher A. (Princeton University)
- Datta, Sujit S. (Princeton University)
Author and Affiliation Lines
Christopher A. Browne and Sujit S. Datta
Princeton University, Princeton, NJ
Speaker / Presenter
Datta, Sujit S.
Keywords
experimental methods; theoretical methods; computational methods; flow-induced instabilities; microscopy; polymer solutions
Text of Abstract
Polymer solutions are often injected in porous media for applications such as oil recovery and groundwater remediation. In many cases, the macroscopic flow resistance abruptly increases above a threshold flow rate in a porous medium, but not in bulk solution. The reason why has been a puzzle for over half a century. Here, by directly visualizing the flow in a transparent 3D porous medium, we demonstrate that this anomalous increase is due to the onset of an elastic instability (often termed ‘elastic turbulence’) in which the flow exhibits strong spatio-temporal fluctuations reminiscent of inertial turbulence, despite the vanishingly small Reynolds number. We quantitatively establish that the energy dissipated by unstable pore-scale fluctuations generates the anomalous increase in flow resistance through the entire medium. Moreover, we show that this finding applies across porous media with different mean grain sizes and generalize it to the case of flow in media with different degrees of structural heterogeneity. Finally, we show how elastic turbulence can be used to homogenize flow in structurally-heterogeneous porous media, and develop quantitative principles to predict and control this flow homogenization for a given medium. Thus, by linking the onset of unstable flow at the pore scale to transport at the macroscale, our work provides generally-applicable guidelines for polymer solution flows in a variety of porous media.