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Rayleigh–Taylor instability in porous media under sinusoidal time-dependent flow displacements

Youssef Elgahawy, Jalel Azaiez

2020AIP Advances16 citationsDOIOpen Access PDF

Abstract

Linear stability analysis and nonlinear simulations have been carried out to analyze the Rayleigh–Taylor instability in homogeneous porous media under time-dependent flow displacements. The flow processes consist of a sinusoidal time-dependent velocity characterized by its period (T) and amplitude (Γ) and ensure that the same amount of fluid is injected over a full flow period. A new, more efficient approach to determine instability characteristics has been developed for the stability analysis of these time-dependent injection flows and showed a growth rate that varies in time like the displacement velocity. The effects of the period T and amplitude Γ as well as the fluids’ viscosity (R) and density differences (ΔG) have been analyzed. Consistent with constant injection displacements, a larger ΔG leads to stronger instabilities. Furthermore, it is found that a larger R tends to attenuate the instability during extraction and soaking periods and to enhance it during injection. This study also revealed that for a given total injection time, the time-dependent flow can be less or more unstable than its constant injection counterpart. In particular, for Γ < −1, larger periods lead to stronger instabilities with longer more developed fingers. For Γ > 1, on the other hand, it is found that larger periods tend to attenuate the instability resulting in a smaller number of fingers and a more diffused front. Flows with unit amplitude (Γ = 1) exhibit the same qualitative trends as but are overall more unstable than their counterparts with Γ > 1.

Topics & Concepts

InstabilityAmplitudeMechanicsRayleigh–Taylor instabilityViscosityFlow (mathematics)Porous mediumConstant (computer programming)Flow velocityPhysicsThermodynamicsChemistryMaterials sciencePorosityOpticsComposite materialComputer scienceProgramming languageEnhanced Oil Recovery TechniquesFluid Dynamics and Turbulent FlowsHydraulic Fracturing and Reservoir Analysis
Rayleigh–Taylor instability in porous media under sinusoidal time-dependent flow displacements | Litcius