Global Regularity for Axisymmetric Navier--Stokes Flows with Swirl

Abstract

We prove global smoothness for smooth finite-energy axisymmetric solutions of the three-dimensional incompressible Navier--Stokes equations with arbitrary swirl. The proof is organized around the circulation \(Γ=ruθ\), the lifted azimuthal vorticity ratio \(G=ωθ/r\), and the axis-compatible circulation-gradient pair \[ Ξ=(A,W)=(Γrr,Γzr). \] The principal near-axis difficulty is the source term \(∂z(F2)\), where \(F=uθ/r=Γ/r2\), in the lifted \(G\)-equation. The first key observation is the exact identity \[ ∂z(F2)=2ΓWr3, dμ5=r3\,dr\,dz, \] which converts the source pairing into \(2∫ GΓW\,drdz\). This term is controlled by an axis Hardy formula for \(Γ\), one-dimensional Sobolev estimates in the axial variable for radial energy densities, and the positive \(W/r\)-Hardy term in the \(Ξ\)-dissipation. The second key point is that the typed zero-output endpoint is no longer treated as an abstract bridge-profile problem. After all source, collar, macro, motion, projection, cascade, and backward-ancestor channels vanish, a small-threshold energy-seeding lemma gives \[ G∈ Lt∞ L2(dμ5) Lt2 H1(dμ5). \]