Understanding Q-Balls Beyond the Thin-Wall Limit
Abstract
Complex scalar fields charged under a global U(1) symmetry can admit non-topological soliton configurations called Q-balls which are stable against decay into individual particles or smaller Q-balls. These Q-balls are interesting objects within quantum field theory, but are also of phenomenological interest in several cosmological and astrophysical contexts. The Q-ball profiles are determined by a nonlinear differential equation, and so generally require solution by numerical methods. In this work, we derive analytical approximations for the Q-ball profile in a polynomial potential and obtain simple expressions for the important Q-ball properties of charge, energy, and radius. These results improve significantly on the often-used thin-wall approximation and make it possible to describe Q-balls to excellent precision without having to solve the underlying differential equation.
Cite
@article{arxiv.2009.08462,
title = {Understanding Q-Balls Beyond the Thin-Wall Limit},
author = {Julian Heeck and Arvind Rajaraman and Rebecca Riley and Christopher B. Verhaaren},
journal= {arXiv preprint arXiv:2009.08462},
year = {2021}
}
Comments
26 pages, v2: matches published version; v3: fixed typo in Eq.(3)