Please use this identifier to cite or link to this item: http://dspace.iitrpr.ac.in:8080/xmlui/handle/123456789/378
Title: Non-modal linear stability analysis of miscible viscous fingering in porous media
Authors: Hota, T.K.
Pramanik, S.
Mishra, M.
Keywords: Diffusion
Direct numerical simulation
Finite difference method
Flow of fluids
Initial value problems
Linear stability analysis
Modal analysis
Numerical methods
Numerical models
Porous materials
Singular value decomposition
Stability Convection-diffusion equations
External excitation
Fourth order Runge-Kutta methods
Initial conditions
Optimal perturbation
Perturbed equations
Pseudospectral methods
Transient behavior
Issue Date: 17-Nov-2016
Abstract: The nonmodal linear stability of miscible viscous fingering in a two-dimensional homogeneous porous medium has been investigated. The linearized perturbed equations for Darcy's law coupled with a convection-diffusion equation is discretized using a finite difference method. The resultant initial value problem is solved by a fourth-order Runge-Kutta method, followed by a singular value decomposition of the propagator matrix. Particular attention is given to the transient behavior rather than the long-time behavior of eigenmodes predicted by the traditional modal analysis. The transient behaviors of the response to external excitations and the response to initial conditions are studied by examining the ε-pseudospectra structures and the largest energy growth function, respectively. With the help of nonmodal stability analysis we demonstrate that at early times the displacement flow is dominated by diffusion and the perturbations decay. At later times, when convection dominates diffusion, perturbations grow. Furthermore, we show that the dominant perturbation that experiences the maximum amplification within the linear regime lead to the transient growth. These two important features were previously unattainable in the existing linear stability methods for miscible viscous fingering. To explore the relevance of the optimal perturbation obtained from nonmodal analysis, we performed direct numerical simulations using a highly accurate pseudospectral method. Furthermore, a comparison of the present stability analysis with existing modal and initial value approach is also presented. It is shown that the nonmodal stability results are in better agreement than the other existing stability analyses, with those obtained from direct numerical simulations.
URI: http://localhost:8080/xmlui/handle/123456789/378
Appears in Collections:Year-2015

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