Probing the γγ* η() Transition Form Factors with Newly Derived η()-Meson Light-Cone Distribution Amplitudes

Abstract

In the present work, we analyze the properties of the transition form factors (TFFs) for the γγ* η() process, employing the η()-meson light-cone distribution amplitude (LCDA) derived within the light-cone sum rule framework. To this end, we adopt the quark-flavor mixing scheme for the η() meson, and compute the TFFs by systematically incorporating transverse-momentum corrections and contributions beyond the leading Fock state. We utilize light-cone harmonic oscillator models to parameterize the longitudinal and transverse behavior of the leading-twist light-cone wavefunction, for which the corresponding LCDA exhibits a unimodal profile. We further examine the potential contributions of intrinsic charm components to the scaled TFFs Q2 Fηγ(Q2) and Q2 Fη γ(Q2). Leveraging a range of values for the decay constant fηc0 and implementing the η-η'-ηc and η-η-G-ηc mixing mechanisms accordingly, together with the recently updated mixing angles, we investigate the impact of the intrinsic cc and gluonic component on these observables. In high-Q2 regime, Q2 Fηγ(Q2) exhibits a marked increase in sensitivity to the charm quark component, whereas Q2Fηγ(Q2) becomes notably stabilized. A detailed discussion of 2/d.o.f and p-values indicates that the intrinsic charm quark component is important and yields a substantial, non-negligible contribution across the entire Q2 range.