Polarization analysis of χcJ decay into octet baryonic pairs

Abstract

This work presents a comprehensive analysis of polarization transfer in the decays \(χcJ\) (\(J=0,1,2\)) to octet baryon-antibaryon pairs within a polarized electron-positron collision environment. Using the spin density matrix formalism, we trace the polarization from the initial beams through the production chain \(e+e- ψ(2S) γχcJ\) to the final-state baryon-antibaryon system. The helicity amplitude analysis for \(χc1 BB\) confirms the universal angular distribution parameter \(α= -1/3\), as dictated by the charge-conjugation helicity selection rule. For \(χc2\) decays, \(α\) and the transverse polarization depend on two independent amplitudes, and our quark-model calculations agree with existing data. We demonstrate that the longitudinal beam polarization \(Pz\) modifies the spin observables for \(χc1\) and \(χc2\), offering new experimental handles at future polarized facilities like the Super \(τ\)-Charm Facility(STCF) to test decay mechanisms and explore baryonic spin entanglement as a quantum information resource.