Three-body unitary coupled-channel approach to radiative J/ decays and η(1405/1475)

Abstract

Recent BESIII data on radiative J/ decays from 1010 J/ samples should significantly advance our understanding of the controversial nature of η(1405/1475). This motivates us to develop a three-body unitary coupled-channel model for radiative J/ decays to three-meson final states of any partial wave (JPC). Basic building blocks of the model are bare resonance states such as η(1405/1475) and f1(1420), and π K, KK, and πη two-body interactions that generate resonances such as K*(892), K*0(700), and a0(980). This model reasonably fits KSKSπ0 Dalitz plot pseudo data generated from the BESIII's JPC=0-+ amplitude for J/γ KSKSπ0. The experimental branching ratios of η(1405/1475)ηππ and η(1405/1475)γ relative to that of η(1405/1475) KKπ are simultaneously fitted. Our 0-+ amplitude is analytically continued to find three poles, two of which correspond to η(1405) on different Riemann sheets of the K*K channel, and the third one for η(1475). This is the first pole determination of η(1405/1475) and, furthermore, the first-ever pole determination from analyzing experimental Dalitz plot distributions with a manifestly three-body unitary coupled-channel framework. Process-dependent ηππ, γπ+π-, and πππ lineshapes of J/γ(0-+) γ(ηππ), γ(γ), and γ(πππ) are predicted, and are in reasonable agreement with data. A triangle singularity is shown to play a crucial role to cause the large isospin violation of J/γ(πππ).

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