KAM for Vortex Patches

    2024, Volume 29, Number 4, pp.  654-676

    Author(s): Berti M.

    In the last years substantial mathematical progress has been made in KAM theory for quasi-linear/fully nonlinear Hamiltonian partial differential equations, notably for water waves and Euler equations. In this survey we focus on recent advances in quasi-periodic vortex patch solutions of the $2d$-Euler equation in $\mathbb R^2 $ close to uniformly rotating Kirchhoff elliptical vortices, with aspect ratios belonging to a set of asymptotically full Lebesgue measure. The problem is reformulated into a quasi-linear Hamiltonian equation for a radial displacement from the ellipse. A major difficulty of the KAM proof is the presence of a zero normal mode frequency, which is due to the conservation of the angular momentum. The key novelty to overcome this degeneracy is to perform a perturbative symplectic reduction of the angular momentum, introducing it as a symplectic variable in the spirit of the Darboux – Carathéodory theorem of symplectic rectification, valid in finite dimension. This approach is particularly delicate in an infinite-dimensional phase space: our symplectic change of variables is a nonlinear modification of the transport flow generated by the angular momentum itself.
    Keywords: KAM for PDEs, Euler equations, vortex patches, quasi-periodic solutions
    Citation: Berti M., KAM for Vortex Patches, Regular and Chaotic Dynamics, 2024, Volume 29, Number 4, pp. 654-676



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