Chiral Nonet Mixing in $\pi K$ Scattering

TL;DR

This paper investigates the quark composition and mixing of scalar mesons through $k$ scattering analysis using a generalized linear sigma model, successfully predicting resonance properties and phase shifts consistent with experimental data.

Contribution

The study introduces a model with two scalar and two pseudoscalar nonets, providing new insights into scalar meson mixing and resonance predictions in $k$ scattering.

Findings

Good agreement with experimental phase shifts up to 1 GeV in I=1/2 channel

Prediction of a broad light kappa resonance with mass 670-770 MeV

Scattering lengths qualitatively match experimental values

Abstract

The underlying mixing of quark components of scalar mesons is probed in $\pi K$ scattering within a generalized linear sigma model that contains two scalar meson nonets and two pseudoscalar meson nonets (a quark-antiquark and a four-quark). In the leading order of this model, all free parameters have been previously fixed using the mass spectra and several low-energy parameters known from experiment and consistent predictions have been made. As other predictions of the model, in the present work the isospins $I$= 1/2, 3/2 and $J$=0 projection of $\pi K$ scattering amplitude (as well as phase shifts) are computed and compared with experiment. In the $I$=1/2 channel, it is shown that within the uncertainties of the model parameters a good agreement with experimental data up to an energy of about 1 GeV is obtained, whereas in the $I$=3/2 channel there is a better agreement with experiment which extends to about 1.4 GeV. The effect of final state interactions of $\pi K$ in the $I$=1/2 channel is approximated by the K-matrix method and the poles of the unitarized scattering amplitude are found. It is shown that the model predicts a light and broad kappa resonance with a mass and decay width of 670-770 MeV and 640-750 MeV consistent with other prior works. Moreover, the scattering lengths in the $I$=1/2, 3/2 are also computed and shown to qualitatively agree with experiment. The overall predictions presented here further support previous findings that the scalar mesons below and above 1 GeV have substantial underlying mixings and that those below 1 GeV have dominant four-quark substructures while those above 1 GeV are closer to conventional $P$-wave quark-antiquark states.