Operator mixing in massless QCD-like theories and Poincare'-Dulac theorem

Abstract

Recently, a geometric approach to operator mixing in massless QCD-like theories -- that involves canonical forms based on the Poincare'-Dulac theorem for the linear system that defines the renormalized mixing matrix in the coordinate representation Z(x,μ) -- has been advocated in arXiv:2103.15527 . As a consequence, a classification of operator mixing in four cases -- depending on the canonical forms of - γ(g)β(g), with γ(g)=γ0 g2+·s the matrix of the anomalous dimensions and β(g)=-β0 g3 + ·s the beta function -- has been proposed: (I) nonresonant γ0β0 diagonalizable, (II) resonant γ0β0 diagonalizable, (III) nonresonant γ0β0 nondiagonalizable, (IV) resonant γ0β0 nondiagonalizable. In particular, in arXiv:2103.15527 a detailed analysis of the case (I) -- where operator mixing reduces to all orders of perturbation theory to the multiplicatively renormalizable case -- has been provided. In the present paper, following the aforementioned approach, we work out in the remaining three cases the canonical forms for - γ(g)β(g) to all orders of perturbation theory, the corresponding UV asymptotics of Z(x,μ), and the physics interpretation. We also work out in detail physical realizations of the cases (I) and (II).