The $SU(\infty)$ twisted gradient flow running coupling
Abstract
We measure the running of the 't Hooft coupling by performing a step scaling analysis of the Twisted Eguchi-Kawai (TEK) model, the SU() gauge theory on a single site lattice with twisted boundary conditions. The computation relies on the conjecture that finite volume effects for SU(N) gauge theories defined on a 4-dimensional twisted torus are controlled by an effective size parameter , with the torus period. We set the scale for the running coupling in terms of and use the gradient flow to define a renormalized 't Hooft coupling . In the TEK model, this idea allows the determination of the running of the coupling through a step scaling procedure that uses the rank of the group as a size parameter. The continuum renormalized coupling constant is extracted in the zero lattice spacing limit, which in the TEK model corresponds to the large limit taken at fixed value of . The coupling constant is thus expected to coincide with that of the ordinary pure gauge theory at . The idea is shown to work and permits us to follow the evolution of the coupling over a wide range of scales. At weak coupling we find a remarkable agreement with the perturbative two-loop formula for the running coupling.
Cite
@article{arxiv.1412.0941,
title = {The $SU(\infty)$ twisted gradient flow running coupling},
author = {Margarita García Pérez and Antonio González-Arroyo and Liam Keegan and Masanori Okawa},
journal= {arXiv preprint arXiv:1412.0941},
year = {2014}
}
Comments
22 pages, 7 figures