What justifies the dependence of the coupling renormalization constant in the dimensional regularization regulator?

Question

I wanna clarify some issues about renormalization in the $\bar{MS}$ scheme that I glossed over when I first learnt about this stuff. I am following http://arxiv.org/abs/1411.7853 section 3.1. The gluon part of the QCD Lagrangian is considered and the renormalized coupling and gluon field are written

$$g=\bar{\mu}^{\epsilon}Z_gg_R\qquad{}A_{\mu}=\sqrt{Z_A}A_{\mu}^R\tag{10}$$

where $\bar{\mu}=\frac{\mu}{\sqrt{2\pi}}e^{\gamma_E/2}$. It is immediately stated that the renormalization constant takes the form

$$Z_g=1+\frac{\alpha_s(\mu)}{4\pi}\frac{Z_{11}}{\epsilon}+\bigg(\frac{\alpha_s(\mu)}{4\pi}\bigg)^2\bigg(\frac{Z_{22}}{\epsilon^2}+\frac{Z_{21}}{\epsilon}\bigg)\\+\bigg(\frac{\alpha_s(\mu)}{4\pi}\bigg)^3\bigg(\frac{Z_{33}}{\epsilon^3}+\frac{Z_{32}}{\epsilon^2}+\frac{Z_{31}}{\epsilon}\bigg)+\ldots{}\tag{13}$$ I don't see why it should be obvious that $Z_g$ should take this form. What justifies this?

Answer 1

Regularization is nothing more than a deformation in the theory in the UV scale as well as in IR scale, depending on what divergence you are facing. Don't matter how precisely is the deformation, the requirement is that the physical predictions that connect the events in your usual scale need to be insensitive under this deformations (renormalizable theory). So, if your choice of regularization give you finite predictions in your scale of interest this is great and the regularization is fine. (see this lecture notes)

This $Z_g$ is one of the choices that clearly give you finite results by limiting the loop integrals by an dimensional regularization (see this historical paper too of G,'t Hooft) such that each loop contribute like: $$ \sim\bigg(\frac{\alpha_s(\mu)}{4\pi}\bigg)^n\frac{1}{\epsilon^m} $$ where $n$ is the number of vertices and $m$ the number of internal internal lines in the corresponding feynamn diagrams that you want to regularize.