Effect of geometric disorder on chaotic viscoelastic porous media flows

Many practical applications such as enhanced oil recovery or groundwater remediation encounter the flow of a viscoelastic fluid in porous media. Once the flow rate exceeds a critical value in such flows, an elastic instability with a fluctuating flow field is observed, which ultimately transits to a more chaotic and turbulence-like flow structure as the flow rate further increases. In this study, we present an extensive numerical investigation of the flows of viscoelastic fluids in a model porous media consisting of a microchannel with many micropillars placed in it by considering boththeir initial staggered and aligned configurations. Within the present range of conditions encompassed in this study, we find that the geometric disorder always increases the chaotic fluctuations irrespective of the initial arrangement ofmicropillars. We propose that it is due to the formation of preferential paths or lanes and the formation of highly curved streamlines in porous media, which results in the local stretching of polymer molecules and hence significant origin in the local elastic stresses. We further show that this chaotic flow behavior is strongly dependent on the competitive influence between the strain-hardening and shear-thinning behaviors of a viscoelastic fluid, which is again strongly dependent on the polymer extensibility parameter, polymer viscosity ratio, and geometric disorder parameter. In particular,we show that the strain-hardening behaviour of a viscoelastic fluid promotes these chaotic fluctuations, whereas the shear-thinning behaviour tends to suppress these.

[1]  A. Shen,et al.  Stagnation points control chaotic fluctuations in viscoelastic porous media flow , 2021, Proceedings of the National Academy of Sciences.

[2]  V. Steinberg Elastic Turbulence: An Experimental View on Inertialess Random Flow , 2021 .

[3]  Jeffrey S. Guasto,et al.  Disorder Suppresses Chaos in Viscoelastic Flows. , 2019, Physical review letters.

[4]  Christopher A. Browne,et al.  Pore-Scale Flow Characterization of Polymer Solutions in Microfluidic Porous Media. , 2019, Small.

[5]  J. Padding,et al.  Lane change in flows through pillared microchannels , 2016, 1607.03672.

[6]  M. A. Alves,et al.  Stabilization of an open-source finite-volume solver for viscoelastic fluid flows , 2017 .

[7]  G. Iaccarino,et al.  Effects of viscoelasticity in the high Reynolds number cylinder wake , 2012, Journal of Fluid Mechanics.

[8]  Taha Sochi,et al.  Non-Newtonian flow in porous media , 2010 .

[9]  F. Pinho,et al.  A convergent and universally bounded interpolation scheme for the treatment of advection , 2003 .

[10]  A. Groisman,et al.  Elastic turbulence in a polymer solution flow , 2000, Nature.

[11]  Hrvoje Jasak,et al.  A tensorial approach to computational continuum mechanics using object-oriented techniques , 1998 .

[12]  Robert A. Handler,et al.  Direct numerical simulation of the turbulent channel flow of a polymer solution , 1997 .

[13]  G. McKinley,et al.  Rheological and geometric scaling of purely elastic flow instabilities , 1996 .

[14]  Pakdel,et al.  Elastic Instability and Curved Streamlines. , 1996, Physical review letters.

[15]  R. Bird,et al.  Constitutive equations for polymeric liquids , 1995 .

[16]  M. A. Ajiz,et al.  A robust incomplete Choleski‐conjugate gradient algorithm , 1984 .