Transition and Stability of 3D MHD Around Couette Flow
Abstract
We study the three-dimensional incompressible magnetohydrodynamic (MHD) equations near Couette flow with a constant magnetic field perpendicular to the shear plane. Couette flow induces mixing and generates magnetic induction, while the constant magnetic field stabilizes z-dependent modes. In contrast, the z-averaged magnetic field exhibits algebraic growth. Letting μ denote the inverse fluid and magnetic Reynolds numbers, we analyze how μ governs stability thresholds in Sobolev spaces. We identify a nonlinear transient-growth regime characterized by the sharp threshold 5/6 γ 1 . For x-average-free initial data of size μγ, solutions are nonlinearly stable; however, for certain initial data, the solution departs from the linear dynamics at rate μγ-1 due to a first-order nonlinear instability. The exponent γ = 5/6 is optimal for the associated energy functional and cannot be improved in Sobolev spaces without secondary transient-growth mechanisms. Below this threshold, solutions necessarily transition away from the linear dynamics at a minimal rate. As a consequence, the 3d results yield sharp Sobolev stability thresholds for the 2d MHD equations around Couette flow without a constant magnetic field. In particular, the threshold is strictly larger than in prior 2d results with a constant field, revealing destabilizing effects normally suppressed by a constant magnetic field. Crucially, this stabilization is restricted to the direction of the magnetic field.
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