Juan Davila, Manuel del Pino, Monica Musso, Juncheng Wei
Published 2018-02-28Version 1
A classical problem for the two-dimensional Euler flow for an incompressible fluid confined to a smooth domain. is that of finding regular solutions with highly concentrated vorticities around $N$ moving {\em vortices}. The formal dynamic law for such objects was first derived in the 19th century by Kirkhoff and Routh. In this paper we devise a {\em gluing approach} for the construction of smooth $N$-vortex solutions. We capture in high precision the core of each vortex as a scaled finite mass solution of Liouville's equation plus small, more regular terms. Gluing methods have been a powerful tool in geometric constructions by {\em desingularization}. We succeed in applying those ideas in this highly challenging setting.
The vortex dynamics of a Ginzburg-Landau system under pinning effect
Vortex dynamics in the presence of excess energy for the Landau-Lifschitz-Gilbert equation
Gluing methods for quantitative stability of optimal transport maps
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