Unitary model analysis of f0(500) pole positions by continuously varying mπ: comparison with discrete lattice predictions

Abstract

Resonance, bound-state, and virtual-state pole positions of the f0(500) scalar meson are computed as a continuous function of pion mass in the framework of a unitarized and analytic coupled-channel model for scalar mesons, described as dynamical quark-antiquark states. The f0(500) is modeled with both light and strange qq seeds, mixing with each other through the common S-wave ππ, KK, and ηη meson-meson decay channels. The few model parameters are fitted to experimental S-wave ππ phase shifts up to 1 GeV. In the case of the physical π mass of 139.57 MeV, resonance poles at (460-i222) MeV and (978-i37.2) MeV are found for the f0(500) and f0(980), respectively. Resonance, bound-state, and virtual-state pole trajectories are computed and plotted as a function of pion masses up to 500 MeV, both in the complex-energy and complex-momentum planes. The results are discussed and compared to the most advanced lattice QCD computations employing interpolators that correspond to the qq and meson-meson channels in the present model, that is, for a few discrete values of the unphysical pion mass in those lattice calculations.