A differential-geometry approach to operator mixing in massless QCD-like theories and Poincar\'e-Dulac theorem

TL;DR

This paper applies differential geometry and the Poincaré-Dulac theorem to classify operator mixing in massless QCD-like theories, providing conditions for simplification and analyzing implications of unitarity and conformal invariance.

Contribution

It introduces a differential-geometry framework for understanding operator mixing and derives conditions for simplifying the mixing matrix in massless QCD-like theories.

Findings

Classification of operator mixing cases based on the matrix A(g)

A sufficient condition for A(g) to be one-loop exact

Diagonalizability of gamma_0 in conformal and unitary theories

Abstract

We review recent progress on operator mixing in the light of the theory of canonical forms for linear systems of differential equations and, in particular, of the Poincar\'e-Dulac theorem. We show that the matrix $A(g) = -\frac{\gamma(g)}{\beta(g)} =\frac{\gamma_0}{\beta_0}\frac{1}{g} + \cdots $ determines which different cases of operator mixing can occur, and we review their classification. We derive a sufficient condition for $A(g)$ to be set in the one-loop exact form $A(g) = \frac{\gamma_0}{\beta_0}\frac{1}{g}$. Finally, we discuss the consequences of the unitarity requirement in massless QCD-like theories, and we demonstrate that $\gamma_0$ is always diagonalizable if the theory is conformal invariant and unitary in its free limit at $g =0$.