Stability and bifurcation of Navier-Stokes equations in an annular domain with mixed boundary conditions

Abstract

We study the existence and stability of non-trivial steady-state solutions to the two-dimensional incompressible Navier-Stokes equations in an annular domain = B(0,b) B(0,a) with radii b>a>0.The outer boundary ∂ B(0, b) is subject to the free condition, while the inner boundary ∂ B(0, a) obeys a Navier-slip condition with effective slip length α > 0. Our main results are fourfold. First, we establish global-in-time strong solutions and derive a sharp energy estimate that underpins the subsequent nonlinear instability analysis. Second, for α > 0, we compute an explicit critical viscosity μc:=μc(α, a,b,μ) that separates qualitatively different dynamical behaviours. Third, we precisely characterize the stability properties of the trivial solution in three distinct regimes. The zero solution is globally asymptotically stable in H2 if μ > μc. If μ = μc, we prove an alternative theorem that completely describes the local dynamics near the trivial state. If μ < μc, the trivial solution is nonlinearly unstable in every Lp (p ≥ 1).Finally, we demonstrate that for μ < μc, the system undergoes a pitchfork bifurcation that generates an infinite family of non-trivial steady states. For generic choices of (α,b), this bifurcation is supercritical; a measurable subset of parameter space yields subcritical transitions. Notably, all bifurcating solutions share the same topological pattern-a single row of counter-rotating vortices-despite their mathematical non-uniqueness.