Stationary ring solitons in field theory — Knots and vortons

Stationary ring solitons in field theory — Knots and vortons

We review the current status of the problem of constructing classical field theory solutions describing stationary vortex rings in Minkowski space in 3+1 dimensions. We describe the known up to date solutions of this type, such as the static knot solitons stabilized by the topological Hopf charge, t...

Full description

Saved in:
Bibliographic Details
Published in:Physics reports Vol. 468; no. 4; pp. 101 - 151
Main Authors: Radu, Eugen, Volkov, Mikhail S.
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01-11-2008
Elsevier
Subjects:
Classical field theory
Exact sciences and technology
Gauge fields
Physics
Solitons
Vortices
11.10.Lm
11.27.+d
Classical field theory
Vortices
Solitons
Gauge fields
98.80.Cq
Sphaleron
Field theories
Minkowski metric
Superfluid
Minkowski space
Chern-Simons theory
11,10.Lm
Topological charges
Gauge field
Monopoles
Boundary-value problems
Ferromagnetism
Nonlinear optics
Steady state solution
Skyrmions
Bose-Einstein condensation
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We review the current status of the problem of constructing classical field theory solutions describing stationary vortex rings in Minkowski space in 3+1 dimensions. We describe the known up to date solutions of this type, such as the static knot solitons stabilized by the topological Hopf charge, the attempts to gauge them, the anomalous solitons stabilized by the Chern–Simons number, as well as the non-Abelian monopole and sphaleron rings. Passing to the rotating solutions, we first discuss the conditions ensuring that they do not radiate, and then describe the spinning Q -balls, their twisted and gauged generalizations reported here for the first time, spinning skyrmions, and rotating monopole–antimonopole pairs. We then present the first explicit construction of global vortons as solutions of the elliptic boundary value problem, which demonstrates their non-radiating character. Finally, we describe the analogs of vortons in the Bose–Einstein condensates, analogs of spinning Q -balls in the non-linear optics, and also moving vortex rings in superfluid helium and in ferromagnetics.
ISSN:0370-1573
1873-6270
DOI:10.1016/j.physrep.2008.07.002