Onset of thermo-convective instabilities in two-layer binary fluid systems
Abstract
The current work analyses the onset characteristics of buoyancy and thermocapillary-driven instabilities in two-layer binary fluid systems near their upper critical solution temperature (UCST). The dynamics of the binary fluids are modelled here via a diffuse interface approach (phase-field method) involving a modified free energy formulation to capture the temperature-dependent solubility and interfacial width. Using spectral collocation-based discretization and a suitable grid mapping strategy, the present work accurately predicts the neutral curves for different fluid combinations that adhere to the concept of balanced contrasts. In the case of pure buoyancy-driven (Rayleigh-Benard) convection, the parametric range for oscillatory onset is found to shrink when the system approaches USCT, as the increased solubility results in less favourable conditions for oscillatory onset. The marginal stability curves of each fluid combination exhibit their own drift pattern based on the thermo-physical and transport properties. For systems with added thermocapillarity effects (Rayleigh-Benard-Marangoni convection), the changing solubilities and the interfacial thickness act along with the interfacial tension to exhibit a dual role that results in system-specific expansion/shrinkage of the parametric space for oscillatory flow onset.
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