Scale setting of SU($N$) Yang--Mills theory, topology and large-$N$ volume independence

TL;DR

This paper establishes the scale of SU(N) Yang--Mills theories for N=3,5,8, and in the large-N limit using gradient flow, twisted boundary conditions, and advanced algorithms to improve accuracy and control finite-size effects.

Contribution

It introduces a novel setup combining twisted boundary conditions and Parallel Tempering to accurately determine scales and topological effects in large-N Yang--Mills theories.

Findings

Achieved accurate scale setting down to 0.025 fm lattice spacing.

Quantified finite-size effects and topological freezing suppression.

Demonstrated large-N volume reduction effects.

Abstract

We set the scale of SU($N$) Yang--Mills theories for $N=3,5,8$ and in the large-$N$ limit via gradient flow, as a first step towards the computation of the large-$N$ $\Lambda$-parameter using step scaling. We adopt twisted boundary conditions to achieve large-$N$ volume reduction and the Parallel Tempering on Boundary Conditions algorithm to tame topological freezing. This setup allows accurate determinations of the gradient-flow scales down to lattice spacings as fine as $\sim 0.025$ fm for all the explored values of $N$, a regime that has never been reached with ergodic algorithms. Moreover, we are able to precisely estimate the finite-size systematics related to topological freezing, and to show the suppression of finite-volume effects expected by virtue of large-$N$ twisted volume reduction.