Two-Loop Rational Terms in Yang-Mills Theories
Abstract
Scattering amplitudes in dimensions involve particular terms that originate from the interplay of UV poles with the dimensional parts of loop numerators. Such contributions can be controlled through a finite set of process-independent rational counterterms, which make it possible to compute loop amplitudes with numerical tools that construct the loop numerators in four dimensions. Building on a recent study [1] of the general properties of two-loop rational counterterms, in this paper we investigate their dependence on the choice of renormalisation scheme. We identify a nontrivial form of scheme dependence, which originates from the interplay of mass and field renormalisation with the dimensional parts of loop numerators, and we show that it can be controlled through a new kind of one-loop counterterms. This guarantees that the two-loop rational counterterms for a given renormalisable theory can be derived once and for all in terms of generic renormalisation constants, which can be adapted a posteriori to any scheme. Using this approach, we present the first calculation of the full set of two-loop rational counterterms in Yang-Mills theories. The results are applicable to SU(N) and U(1) gauge theories coupled to fermions with arbitrary masses.
Cite
@article{arxiv.2007.03713,
title = {Two-Loop Rational Terms in Yang-Mills Theories},
author = {Jean-Nicolas Lang and Stefano Pozzorini and Hantian Zhang and Max F. Zoller},
journal= {arXiv preprint arXiv:2007.03713},
year = {2020}
}
Comments
Typo fixed in (4.83). References added. Version to appear in JHEP