One-loop kink mass shifts: a computational approach
Abstract
In this paper we develop a procedure to compute the one-loop quantum correction to the kink masses in generic (1+1)-dimensional one-component scalar field theoretical models. The procedure uses the generalized zeta function regularization method helped by the Gilkey-de Witt asymptotic expansion of the heat function via Mellin's transform. We find a formula for the one-loop kink mass shift that depends only on the part of the energy density with no field derivatives, evaluated by means of a symbolic software algorithm that automates the computation. The improved algorithm with respect to earlier work in this subject has been tested in the sine-Gordon and models. The quantum corrections of the sG-soliton and -kink masses have been estimated with a relative error of 0.00006% and 0.00007% respectively. Thereafter, the algorithm is applied to other models. In particular, an interesting one-parametric family of double sine-Gordon models interpolating between the ordinary sine-Gordon and a re-scaled sine-Gordon model is addressed. Another one-parametric family, in this case of models, is analyzed. The main virtue of our procedure is its versatility: it can be applied to practically any type of relativistic scalar field models supporting kinks.
Cite
@article{arxiv.1107.2216,
title = {One-loop kink mass shifts: a computational approach},
author = {Alberto Alonso-Izquierdo and Juan Mateos Guilarte},
journal= {arXiv preprint arXiv:1107.2216},
year = {2011}
}
Comments
35 pages, 6 figures, to be published in Nuclear Physics B