Role of the σ-resonance in determining the convergence of chiral perturbation theory

Abstract

The dimensionless parameter = Mπ2/(16 π2 Fπ2), where Fπ is the pion decay constant and Mπ is the pion mass, is expected to control the convergence of chiral perturbation theory applicable to QCD. Here we demonstrate that a strongly coupled lattice gauge theory model with the same symmetries as two-flavor QCD but with a much lighter σ-resonance is different. Our model allows us to study efficiently the convergence of chiral perturbation theory as a function of . We first confirm that the leading low energy constants appearing in the chiral Lagrangian are the same when calculated from the p-regime and the ε-regime as expected. However, 0.002 is necessary before 1-loop chiral perturbation theory predicts the data within 1%. For > 0.0035 the data begin to deviate dramatically from 1-loop chiral perturbation theory predictions. We argue that this qualitative change is due to the presence of a light σ-resonance in our model. Our findings may be useful for lattice QCD studies.