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ЖУРНАЛЫ // Regular and Chaotic Dynamics // Архив

Regul. Chaotic Dyn., 2017, том 22, выпуск 7, страницы 865–879 (Mi rcd296)

Эта публикация цитируется в 11 статьях

On Stability of Thomson’s Vortex $N$-gon in the Geostrophic Model of the Point Bessel Vortices

Leonid G. Kurakinab, Irina V. Ostrovskayaa

a Institute for Mathematics, Mechanics and Computer Sciences, Southern Federal University, ul. Milchakova 8a, Rostov-on-Don, 344090 Russia
b Southern Mathematical Institute, Vladikavkaz Scienific Center of RAS, ul. Markusa 22, Vladikavkaz, 362027 Russia

Аннотация: A stability analysis of the stationary rotation of a system of $N$ identical point Bessel vortices lying uniformly on a circle of radius $R$ is presented. The vortices have identical intensity $\Gamma$ and length scale $\gamma^{-1}>0$. The stability of the stationary motion is interpreted as equilibrium stability of a reduced system. The quadratic part of the Hamiltonian and eigenvalues of the linearization matrix are studied. The cases for $N=2,\ldots,6$ are studied sequentially. The case of odd $N=2\ell+1\geqslant 7$ vortices and the case of even $N=2n\geqslant 8$ vortices are considered separately. It is shown that the $(2\ell+1)$-gon is exponentially unstable for $0<\gamma R<R_*(N)$. However, this $(2\ell+1)$-gon is stable for $\gamma R\geqslant R_*(N)$ in the case of the linearized problem (the eigenvalues of the linearization matrix lie on the imaginary axis). The even $N=2n\geqslant 8$ vortex $2n$-gon is exponentially unstable for $R>0$.

Ключевые слова: $N$-vortex problem, point Bessel vortices, Hamiltonian dynamics, stability.

MSC: 76B47, 76E20, 34D20

Поступила в редакцию: 31.08.2017
Принята в печать: 30.10.2017

Язык публикации: английский

DOI: 10.1134/S1560354717070085



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