Dispersive analysis of the φ γ π0 π0 process

Abstract

We present an analysis of the radiative decay φ γ π0 π0 in a dispersive framework, where the two-pion subsystem undergoes strong final-state interactions that cover the f0(500) and f0(980) regions. We employ a coupled-channel Muskhelishvili-Omn\`es framework that allows for a consistent treatment of two scalar resonances and crossed-channel singularities induced by the Born and vector-meson exchanges. We explicitly verify the equivalence between the modified and standard Muskhelishvili-Omn\`es representations for vector-meson pole contributions when the isoscalar Omn\`es matrix is chosen asymptotically bounded, and we adopt the standard representation in decay kinematics. This yields, for the first time, a parameter-free dispersive prediction for the kaon Born rescattering, which provides a dominant contribution. To obtain a good fit to the KLOE and SND data, we employ a once-subtracted coupled-channel dispersion relation with heavier left-hand cut contributions and two unknown subtraction constants. The results demonstrate the consistency among the data for ππ scattering, γγ fusion, and φ radiative decay, thereby validating the underlying dispersive formalism and the input used for the hadronic Omn\`es matrix and left-hand cuts.