On the geometry of operator mixing in massless QCD-like theories

Abstract

We revisit the operator mixing in massless QCD-like theories. In particular, we address the problem of determining under which conditions a renormalization scheme exists where the renormalized mixing matrix in the coordinate representation, Z(x, μ), is diagonalizable to all perturbative orders. As a key step, we provide a differential-geometric interpretation of renormalization that allows us to apply the Poincar\'e-Dulac theorem to the problem above: We interpret a change of renormalization scheme as a (formal) holomorphic gauge transformation, -γ(g)β(g) as a (formal) meromorphic connection with a Fuchsian singularity at g=0, and Z(x,μ) as a Wilson line, with γ(g)=γ0 g2 + ·s the matrix of the anomalous dimensions and β(g)=-β0 g3 +·s the beta function. As a consequence of the Poincar\'e-Dulac theorem, if the eigenvalues λ1, λ2, ·s of the matrix γ0β0, in nonincreasing order λ1 ≥ λ2 ≥ ·s, satisfy the nonresonant condition λi -λj -2k ≠ 0 for i≤ j and k a positive integer, then a renormalization scheme exists where -γ(g)β(g) = γ0β0 1g is one-loop exact to all perturbative orders. If in addition γ0β0 is diagonalizable, Z(x, μ) is diagonalizable as well, and the mixing reduces essentially to the multiplicatively renormalizable case. We also classify the remaining cases of operator mixing by the Poincar\'e-Dulac theorem.