Criticality of the Axially Symmetric Navier-Stokes Equations

Abstract

Smooth solutions to the axi-symmetric Navier-Stokes equations obey the following maximum principle: t≥ 0\|rvθ(t, ·)\|L∞ ≤ \|rvθ(0, ·)\|L∞. We prove that all solutions with initial data in H12 is smooth globally in time if rvθ satisfies a kind of Form Boundedness Condition (FBC) which is invariant under the natural scaling of the Navier-Stokes equations. In particular, if rvθ satisfies equation t ≥ 0|rvθ(t, r, z)| ≤ C| r|- 2,\ \ r ≤ δ0 ∈ (0, 12),\ C < ∞, equation then our FBC is satisfied. Here δ0 and C are independent of neither the profile nor the norm of the initial data. So the gap from regularity is logarithmic in nature. We also prove the global regularity of solutions if \|rvθ(0, ·)\|L∞ or t ≥ 0\|rvθ(t, ·)\|L∞(r ≤ r0) is small but the smallness depends on certain dimensionless quantity of the initial data.