2D inviscid Boussinesq equations and 3D axisymmetric Euler equations: (1) A unification (Em), (2) Finite-time blow-up of two unified (1+1)D systems rigorously derived from (Em)
Abstract
We derive a unified polar (1+2)D subsystem (Em), with m=1,2, from the 2D inviscid Boussinesq and 3D axisymmetric Euler equations. On the symmetry axes θ=0,π/2,π, ridge flatness closes the dynamics and gives two exact unified (1+1)D reductions: the horizontal-axis system (R0) and the vertical-axis system (Z0). Their common apex trace is a Constantin--Lax--Majda type ODE that yields finite-time blow-up at x=0. Subsection~seq:vorticity-strain connects this pointwise mechanism with Euler continuation theory: for any compatible axisymmetric realization, explicit apex blow-up forces divergence of the time-integrated L∞ norm of ∇ v, so the singularity is detected by the strain criterion. Section~sec:R0-SS strengthens the reduced mechanism by constructing regular apex-only self-similar profiles for the convective horizontal-axis equation (R0); the resulting solution is bounded away from x=0, blows up at the apex, and satisfies the same strain-divergence condition. Finally, we derive the exact background--remainder equations and state a conditional nonlinear stability framework: if a compatible full background, weighted elliptic/coercive estimates, and a spectral gap exponent are available, then the apex blow-up transfers to the full solution. Thus the rigorous components are the derivation of (Em), (R0), and (Z0), the apex blow-up and strain verification, the apex-only (R0) self-similar construction, and the perturbative framework; the remaining open step is the unconditional construction and control of the full background away from the apex.
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