Simplifying QCD event generation with chirality flow, reference vectors and spin directions
Abstract
The chirality-flow formalism, combined with good choices of gauge reference vectors, simplifies tree-level calculations to the extent that it is often possible to write down amplitudes corresponding to Feynman diagrams immediately. It has also proven to give a very sizable speedup in a proof of concept implementation of massless tree-level QED in MadGraph5_aMC@NLO. In the present paper we extend this analysis to QCD, including massive quarks. We define helicity-dependent versions of the gluon vertices, derive constraints on the spinor structure of propagating gluons, and explore the Schouten identity to simplify the four-gluon vertex further. For massive quarks, the chirality-flow formalism sheds light on how to exploit the freedom to measure spin along any direction to shorten the calculations. Overall, this results in a clear speedup for treating the Lorentz structure at high multiplicities.
Cite
@article{arxiv.2312.07447,
title = {Simplifying QCD event generation with chirality flow, reference vectors and spin directions},
author = {Emil Boman and Andrew Lifson and Malin Sjodahl and Adam Warnerbring and Zenny Wettersten},
journal= {arXiv preprint arXiv:2312.07447},
year = {2024}
}
Comments
30 pages, 4 figures