English

Complex Trkalian Fields and Solutions to Euler's Equations for the Ideal Fluid

chao-dyn 2016-08-31 v1 dg-ga High Energy Physics - Theory Differential Geometry Chaotic Dynamics

Abstract

We consider solutions to the complex Trkalian equation,~×\vc=\vc, \vec{\nabla} \times \vc = \vc , where~\vc\vc is a 3 component vector function with each component in the complex field, and may be expressed in the form~\vc=eigF, \vc = e^{ig} \vec{\nabla} F, with~gg real and~FF complex. We find, there are precisely two classes of solutions; one where~gg is a Cartesian variable and one where~gg is the spherical radial coordinate. We consider these flows to be the simplest of all exact 3-d solutions to the Euler's equation for the ideal incompressible fluid. The novel approach we use in solving for these classes of solutions to these 3-dimensional vector pdes involves differential geometric techniques: one may employ the method to generate solutions to other classes of vector pdes.

Keywords

Cite

@article{arxiv.chao-dyn/9502012,
  title  = {Complex Trkalian Fields and Solutions to Euler's Equations for the Ideal Fluid},
  author = {P. R. Baldwin and G. M. Townsend},
  journal= {arXiv preprint arXiv:chao-dyn/9502012},
  year   = {2016}
}

Comments

30 pages, no figures; to appear-March PRE