Satish Kumar scite author profile

Fluid flow over a deformable solid can become unstable due to the fact that waves may propagate along the solid–fluid interface. In order to understand the role that nonlinear rheological properties of the solid play in these elastohydrodynamic instabilities, we apply linear stability analysis to investigate creeping Couette flow of a Newtonian fluid past an incompressible and impermeable neo-Hookean solid of finite thickness. As inertial effects are assumed to be negligible, the problem is governed by three dimensionless parameters: an imposed strain, a thickness ratio, and an interfacial tension. In the base state, there is a first normal stress difference in the neo-Hookean solid, and this leads to instability behavior that is significantly different from what is observed with a linear constitutive equation. In the absence of interfacial tension, the first normal stress difference gives rise to a shortwave instability. For sufficiently thin solids, a large range of high-wavenumber modes becomes unstable first as the strain that is imposed on the system increases, while for sufficiently thick solids, a small band of O(1) wavenumbers first becomes unstable. The presence of interfacial tension removes the shortwave instability and leads to larger critical imposed strains and smaller critical wavenumbers. In comparison to the linear elastic constitutive equation, the neo-Hookean model leads to smaller values of the critical imposed strain and larger values of the critical wavenumber, but the difference rapidly diminishes as the solid thickness increases. Analysis of the continuity of velocity boundary condition at the interface reveals that at the critical conditions, the mean flow tends to amplify horizontal interface perturbations, while horizontal velocity perturbations tend to suppress them. The results of this work highlight the importance of properly accounting for large displacement gradients when modeling elastohydrodynamic instabilities.

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Instability of viscoelastic plane Couette flow past a deformable wall

Shankar

Kumar

2004

Journal of Non-Newtonian Fluid Mechanics

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Transient growth without inertia

Jovanović¹,

Kumar²

2010

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We study transient growth in inertialess plane Couette and Poiseuille flows of viscoelastic fluids. For streamwise-constant three-dimensional fluctuations, we demonstrate analytically the existence of initial conditions that lead to quadratic scaling of both the kinetic energy density and the elastic energy with the Weissenberg number, We. This shows that in strongly elastic channel flows of viscoelastic fluids, both velocity and polymer stress fluctuations can exhibit significant transient growth even in the absence of inertia. Our analysis identifies the spatial structure of the initial conditions ͑i.e., components of the polymer stress tensor at t =0͒ responsible for this large transient growth. Furthermore, we show that the fluctuations in streamwise velocity and the streamwise component of the polymer stress tensor achieve O͑We͒ and O͑We 2 ͒ growth, respectively, over a time scale O͑We͒ before eventual asymptotic decay. We also demonstrate that the large transient responses originate from the stretching of polymer stress fluctuations by a background shear and draw parallels between streamwise-constant inertial flows of Newtonian fluids and streamwise-constant creeping flows of viscoelastic fluids. One of the main messages of this paper is that at the level of velocity fluctuation dynamics, polymer stretching and the Weissenberg number in elasticity-dominated flows of viscoelastic fluids effectively assume the role of vortex tilting and the Reynolds number in inertia-dominated flows of Newtonian fluids.

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Parametrically driven surface waves in viscoelastic liquids

Kumar¹

1999

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Satish Kumar

Meltblown fibers: Influence of viscosity and elasticity on diameter distribution

Instability of creeping Couette flow past a neo-Hookean solid

Instability of viscoelastic plane Couette flow past a deformable wall

Transient growth without inertia

Parametrically driven surface waves in viscoelastic liquids

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