Stability of plane Couette and Poiseuille flows rotating about the streamwise axis

Abstract

We study the stability of plane Poiseuille flow (PPF) and plane Couette flow (PCF) subject to streamwise system rotation using linear stability analysis and direct numerical simulations. The linear stability analysis reveals two asymptotic regimes depending on the non-dimensional rotation rate (Ro): a low-Ro and a high-Ro regime. In the low-Ro regime, the critical Reynolds number Rec and critical streamwise wavenumber αc are proportional to Ro, while the critical spanwise wavenumber βc is constant. In the high-Ro regime, as Ro → ∞, we find Rec = 66.45 and βc = 2.459 for streamwise rotating PPF, and Rec = 20.66 and βc = 1.558 for streamwise rotating PCF, with αc 1/Ro. Our results for streamwise rotating PPF match previous findings by Masuda et al. (2008). Interestingly, the critical values of βc and Rec at Ro → ∞ in streamwise rotating PPF and PCF coincide with the minimum Rec reported by Lezius & Johnston (1976) and Wall & Nagata (2006) for spanwise rotating PPF at Ro=0.3366 and PCF at Ro=0.5. We explain this similarity through an analysis of the perturbation equations. Consequently, the linear stability of streamwise rotating PCF at large Ro is closely related to that of spanwise rotating PCF and Rayleigh-Benard convection, with Rec = Rac/2, where Rac is the critical Rayleigh number. To explore the potential for subcritical transitions, direct numerical simulations were performed. At low Ro, a subcritical transition regime emerges, characterized by large-scale turbulent-laminar patterns in streamwise rotating PPF and PCF. However, at higher Ro, subcritical transitions do not occur and the flow relaminarizes for Re < Rec. Furthermore, we identify a narrow Ro-range where turbulent-laminar patterns develop under supercritical conditions.

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