Clodoaldo Grotta-Ragazzo, Björn Gustafsson, Jair Koiller
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引用次数: 0
摘要
让 \(\Sigma\) 是一个无边界的紧凑流形,其第一同调为非三维。用 1-forms 对不可压缩的欧拉方程进行霍奇分解,可以得到一个耦合的 PDE-ODE 系统。(L^{2}\)正交分量是 "纯 "涡流和势流(谐波,与同调维度有关)。在本文中,我们关注的是\(g\)属无边界紧凑黎曼曲面上的\(N\)点涡流,其度量在共形类中选择。相空间有有限维度(2N+2g)。我们计算了非平面度量的环面((g=1))上单旋涡((N=1))运动的截面曲面,它显示了不可解的 2 自由度哈密顿的典型特征。与此相反,对于平面环,谐波部分是恒定的。接下来,我们转向具有恒定曲率(-1)和离散对称性的双曲面((g\geqslant 2\))。渐开线的定点产生了波恩卡莱盘中的旋涡晶体。最后,我们考虑多连通平面域。格林和汤姆森提出的图像法在肖特基双重中得到了应用。在 C. C. Lin 的著名定理中给出的 Kirchhoff - Routh Hamiltoniang 通过马斯登 - 温斯坦还原法从 \(2N+2g\) 恢复到 \(2N\)。
On the Interplay Between Vortices and Harmonic Flows: Hodge Decomposition of Euler’s Equations in 2d
Let \(\Sigma\) be a compact manifold without boundary whose first homology is nontrivial. The Hodge decomposition of the incompressible Euler equation in terms of 1-forms yields a coupled PDE-ODE system. The \(L^{2}\)-orthogonal components are a “pure” vorticity flow and a potential flow (harmonic, with the dimension of the homology). In this paper we focus on \(N\) point vortices on a compact Riemann surface without boundary of genus \(g\), with a metric chosen in the conformal class. The phase space has finite dimension \(2N+2g\). We compute a surface of section for the motion of a single vortex (\(N=1\)) on a torus (\(g=1\)) with a nonflat metric that shows typical features of nonintegrable 2 degrees of freedom Hamiltonians. In contradistinction, for flat tori the harmonic part is constant. Next, we turn to hyperbolic surfaces (\(g\geqslant 2\)) having constant curvature \(-1\), with discrete symmetries. Fixed points of involutions yield vortex crystals in the Poincaré disk. Finally, we consider multiply connected planar domains. The image method due to Green and Thomson is
viewed in the Schottky double. The Kirchhoff – Routh Hamiltonian
given in C. C. Lin’s celebrated theorem is recovered by
Marsden – Weinstein reduction from \(2N+2g\) to \(2N\).
The relation between the electrostatic Green function and the
hydrodynamic Green function is clarified.
A number of questions are suggested.
期刊介绍:
Regular and Chaotic Dynamics (RCD) is an international journal publishing original research papers in dynamical systems theory and its applications. Rooted in the Moscow school of mathematics and mechanics, the journal successfully combines classical problems, modern mathematical techniques and breakthroughs in the field. Regular and Chaotic Dynamics welcomes papers that establish original results, characterized by rigorous mathematical settings and proofs, and that also address practical problems. In addition to research papers, the journal publishes review articles, historical and polemical essays, and translations of works by influential scientists of past centuries, previously unavailable in English. Along with regular issues, RCD also publishes special issues devoted to particular topics and events in the world of dynamical systems.
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