Global Regularity of Axisymmetric Navier-Stokes Equations with NHL Boundary Conditions under a Critical Smallness Condition

Abstract

We investigate the global regularity problem for the three-dimensional incompressible Navier-Stokes equations restricted to axisymmetric flows in a finite cylinder D = \(r,θ,x3): 0 r 1, 0 θ< 2π, 0 x3 1\, subject to the Navier-Hodge-Lions (NHL) boundary condition. While global existence of smooth solutions is known in the swirl-free case, the presence of swirl (vθ≠ 0) introduces vortex stretching that may potentially lead to finite-time singularity formation. In this work, we prove that if the initial data satisfy a scaling-invariant smallness condition of the form \[ 9C1C31/24(12\|V0\|L44 + \|Ω0\|L22)1/4\|Γ0\|L4 14, \] where V = vθ/r, Ω= ωθ/r, Γ= r vθ, and C1, C3 are explicit constants given in this paper, then the solution remains globally regular for all time. The proof proceeds via a transformed system for Ω and V, leveraging a maximum principle for Γ, refined Agmon-type inequalities to control \|vr/r\|L∞, and delicate boundary analysis of the finite cylinder geometry. Key energy estimates yield L∞T L4x bounds for all velocity components, which fall within the regularity class, thereby precluding finite-time blow-up. The result extends the known criticality theory for axisymmetric Navier-Stokes flows to the setting of NHL boundary conditions, which are physically relevant for flows with stress-free or slip-type constraints on lateral and horizontal boundaries.