Electrically driven convection in a thin annular film undergoing circular Couette flow
Abstract
We investigate the linear stability of a thin, suspended, annular film of conducting fluid with a voltage difference applied between its inner and outer edges. For a sufficiently large voltage, such a film is unstable to radially-driven electroconvection due to charges which develop on its free surfaces. The film can also be subjected to a Couette shear by rotating its inner edge. This combination is experimentally realized using films of smectic A liquid crystals. In the absence of shear, the convective flow consists of a stationary, azimuthally one-dimensional pattern of symmetric, counter-rotating vortex pairs. When Couette flow is applied, an azimuthally traveling pattern results. When viewed in a co-rotating frame, the traveling pattern consists of pairs of asymmetric vortices. We calculate the neutral stability boundary for arbitrary radius ratio α and Reynolds number R e of the shear flow, and obtain the critical control parameter Rc (α, R e) and the critical azimuthal mode number mc (α, R e). The Couette flow suppresses the onset of electroconvection, so that Rc (α, R e) > Rc (α,0). The calculated suppression is compared with experiments performed at α = 0.56 and 0 ≤ R e ≤ 0.22 .
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