Static cylindrically symmetric dyonic wormholes in the 6-dimensional Kaluza--Klein theory: Exact solutions

TL;DR

This paper derives new exact cylindrically symmetric wormhole solutions in 6-dimensional Kaluza-Klein theory, involving dyonic configurations with electric and magnetic charges, expanding understanding of higher-dimensional wormhole geometries.

Contribution

It presents novel exact solutions for cylindrically symmetric wormholes in 6D Kaluza-Klein theory with dyonic fields, highlighting conditions for internal space symmetry breaking.

Findings

New exact solutions with electric and magnetic fields

Wormholes supported by dyonic charge configurations

Internal space symmetry breaking conditions

Abstract

We study cylindrically symmetric Abelian wormholes (WhC) in $(4+n)$-dimensional Kaluza-Klein theory. It is shown that static, four-dimensional, cylindrically symmetric solutions in $(4+n)$-dimensional Kaluza-Klein theory with maximal Abelian isometry group $U(1)^n$ of the internal space with diagonal internal metric can be obtained, as in the case of a supersymmetric static black hole \cite{Cv}, only if the isometry group of the internal space is broken down to the $U (1)_e \times U(1)_m$ gauge group; they correspond to dyonic configurations with one electric $(Q_e)$ and one magnetic $(Q_m)$ charge that are related either to the same $U(1)_e$ or $U(1)_m$ gauge field or to different factors of the $U (1)_e \times U(1)_m$ gauge group of the effective 6-dimensional Kaluza-Klein theory. We find new exact solutions of the 6-dimensional Kaluza--Klein theory with two Abelian gauge fields, dilaton and scalar fields, associated with the internal metric. We obtain new types of cylindrically symmetric wormholes supported by the radial and longitudinal electric and magnetic fields.