Email this article The vortex filament dynamics: New viewpoint on the problems of energy and effective mass
- Authors: Talalov S.V.1
-
Affiliations:
- Togliatti State University
- Issue: Vol 23, No 1 (2019)
- Pages: 37-48
- Section: Articles
- URL: https://bakhtiniada.ru/1991-8615/article/view/34679
- DOI: https://doi.org/10.14498/vsgtu1652
- ID: 34679
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Abstract
The paper is devoted to the dynamics of a zero thickness infinite vortex filament in the local induction approximation. The filament is asymptotically considered as a straight line defined by the certain vector ${\boldsymbol{b}}_3 \in E_3$.
We also investigate the possibility of interpretation of such object as a planar “quaziparticle”. The configuration space for some “collective coordinates” for such object is the plane $E_2 \perp {\boldsymbol{b}}_3$.
The “quaziparticle” has a certain number of the internal degrees of the freedom. The Hamiltonian description of the filament is constructed in terms of the variables allowing the natural classification into “external” and “internal” groups.
The external variables (coordinates and momenta of a planar structureless particle) and the internal ones (the variables for the continuous Heisenberg spin chain) are entangled by the constraints. Because of these constraints, the constructed theory is non-trivial. The space symmetry group of the system was constructed by two stages: the contraction $ SO(3) \to E(2)$ and the subsequent extension $E(2) \times T \to \tilde{\mathcal G}_2$. The group $E(2)$ is the group of the plane motion for the plane $E_2 \perp {\boldsymbol{b}}_3$, symbol $T$ denotes the group of time translations and the group $\tilde{\mathcal G}_2$ is the central extended Galilei group for the plane mentioned above.
The appearance of the Galilei group makes it possible to introduce the invariant Cazimir functions for the Lee algebras for this group and to formulate the new approach for the problem of the energy of the infinite vortex filament with zero thickness. The formula for the tensor of the inverse effective mass of the constructed system is also being deduced. It is demonstrated that the suggested theory can be interpreted as a model of the planar vortex particle having an infinite number of internal degrees of freedom.
We also investigate the possibility of interpretation of such object as a planar “quaziparticle”. The configuration space for some “collective coordinates” for such object is the plane $E_2 \perp {\boldsymbol{b}}_3$.
The “quaziparticle” has a certain number of the internal degrees of the freedom. The Hamiltonian description of the filament is constructed in terms of the variables allowing the natural classification into “external” and “internal” groups.
The external variables (coordinates and momenta of a planar structureless particle) and the internal ones (the variables for the continuous Heisenberg spin chain) are entangled by the constraints. Because of these constraints, the constructed theory is non-trivial. The space symmetry group of the system was constructed by two stages: the contraction $ SO(3) \to E(2)$ and the subsequent extension $E(2) \times T \to \tilde{\mathcal G}_2$. The group $E(2)$ is the group of the plane motion for the plane $E_2 \perp {\boldsymbol{b}}_3$, symbol $T$ denotes the group of time translations and the group $\tilde{\mathcal G}_2$ is the central extended Galilei group for the plane mentioned above.
The appearance of the Galilei group makes it possible to introduce the invariant Cazimir functions for the Lee algebras for this group and to formulate the new approach for the problem of the energy of the infinite vortex filament with zero thickness. The formula for the tensor of the inverse effective mass of the constructed system is also being deduced. It is demonstrated that the suggested theory can be interpreted as a model of the planar vortex particle having an infinite number of internal degrees of freedom.
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##article.viewOnOriginalSite##About the authors
Sergei Vladimirovich Talalov
Togliatti State University
Email: svt_19@mail.ru
Doctor of physico-mathematical sciences, Associate professor
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