Effect of an aligned current on the stability of oscillatory incompressible flow past a circular cylinder

Abstract

The stability of incompressible flow past a circular cylinder under collinear steady and oscillatory forcing is investigated within a two-dimensional Floquet framework. The flow is parameterised by the Keulegan-Carpenter number KC ∈ [4,12], the steady-to-oscillatory velocity ratio m ∈ [0,1], and the oscillatory Reynolds number Rem ∈ [20,100]. The loci of the leading Floquet multipliers, and hence case-specific bifurcation modes, are examined by progressively reducing Rem to subcritical values for prescribed m. A steady current with m > 0.5 gives rise to a period-doubling subharmonic bifurcation that does not occur in purely oscillatory flow, where only synchronous and quasi-periodic modes arise. For Rem = 100, three key features are discernible. First, the neutral stability curve in (KC,m) space is strongly non-monotonic in m, separating intrinsically stable regions from those with single unstable modes; a sub-region of striking mode re-stabilisation appears beyond m ≈ 0.9, where the flow recovers a Z2-symmetric state at peak Reynolds number ≈ 190, despite the steady and oscillatory components each being individually unstable. Second, a distinct regime supports the coexistence of two unstable modes of different types. Third, complementary direct numerical simulations show that, for a single unstable mode, the linear analysis successfully predicts the saturated nonlinear state even when Rem = 100 substantially exceeds the critical Reynolds number, whereas under mode coexistence the quasi-periodic attractor tends to dominate the developed dynamics.