Long Range Effects of Cosmic String Structure
Abstract
We combine and further develop ideas and techniques of Allen \& Ottewill, Phys. Rev.D, {\bf 42}, 2669 (1990) and Kay \& Studer Commun. Math. Phys., {\bf 139}, 103 (1991) for calculating the long range effects of cosmic string cores on classical and quantum field quantities far from an (infinitely long, straight) cosmic string. We find analytical approximations for (a) the gravity-induced ground state renormalized expectation values of and for a non-minimally coupled quantum scalar field far from a cosmic string (b) the classical electrostatic self force on a test charge far from a superconducting cosmic string. Surprisingly -- even at cosmologically large distances -- all these quantities would be very badly approximated by idealizing the string as having zero thickness and imposing regular boundary conditions; instead they are well approximated by suitably fitted strengths of logarithmic divergence at the string core. Our formula for reproduces (with much less effort and much more generality) the earlier numerical results of Allen \& Ottewill. Both and turn out to be ``weak field topological invariants'' depending on the details of the string core only through the minimal coupling parameter ``'' (and the deficit angle). Our formula for the self-force (leaving aside relatively tiny gravitational corrections) turns out to be attractive: We obtain, for the self-potential of a test charge a distance from a (GUT scale) superconducting string, the formula where is an (in principle, computable) constant of the order of the inverse string radius.
Keywords
Cite
@article{arxiv.gr-qc/9510058,
title = {Long Range Effects of Cosmic String Structure},
author = {Bruce Allen and Bernard S. Kay and Adrian C. Ottewill},
journal= {arXiv preprint arXiv:gr-qc/9510058},
year = {2009}
}
Comments
25 pages, RevTeX with epsfig, 3 Postscript figures