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Renormalization Group Approach to Confinement

High Energy Physics - Lattice 2026-05-20 v2 High Energy Physics - Phenomenology High Energy Physics - Theory Nuclear Theory

Abstract

While we have several complementary models of confinement, some of which are phenomenologically appealing, we do not have the ability to calculate analytically even simple aspects of confinement, let alone have a framework to eventually prove confinement. The problem we are facing is to evolve the theory from the perturbative regime to the long distance confining regime. This is generally achieved by renormalization group transformations. With the gradient flow we now have a technique to address the problem from first principles. The primary focus is on the running coupling αS(μ)\alpha_S(\mu), from which confinement can be concluded alone. A central point is that the gluon condensate is scale invariant, which reflects its self-similar behavior across different scales. Building on that, we derive αS(μ)ΛS2/μ2\alpha_S(\mu) \simeq \Lambda_S^2/\mu^2, which evolves to the infrared fixed point 1/αS=01/\alpha_S = 0 in accordance with infrared slavery. The only important factor appears to be the presence of the gluon condensate, which is a universal feature that QCD shares with many other models. The analytical results are supported by numerical simulations.

Keywords

Cite

@article{arxiv.2509.10658,
  title  = {Renormalization Group Approach to Confinement},
  author = {Gerrit Schierholz},
  journal= {arXiv preprint arXiv:2509.10658},
  year   = {2026}
}

Comments

17 pages, 6 figures, some improvements to the text, matches published version

R2 v1 2026-07-01T05:34:17.568Z