Decoding the role of mesonic states for elucidating the e+e- a2(1320)π data and other reactions

Abstract

Recently, the BESIII Collaboration observed a -like structure Y(2044) in e+e- a2(1320)π, suggesting that Y(2044) may be a candidate of vector meson (2D) by comparing resonance parameters. However, the theoretical prediction for the combined branching ratio e+e-Ba2(1320)π for the pure (2D) state is about two orders of magnitude smaller than the experimental value. To resolve this discrepancy and decipher the nature of Y(2044), this work propose an S-D mixing scheme to reanalyze the cross section of e+e- a2(1320)π, and find that the aforementioned branching ratio discrepancy can be resolved. Our results show that the Y(2044) structure can be reproduced by introducing four theoretically predicted S-D mixing meson states 3S-2D, 3S-2D, 4S-3D, and 4S-3D as intermediate resonances, in which dominant contribution arises from 3S-2D and their inference effect is also significant. Furthermore, we reanalyzed five additional isospin vector processes e+e- ωπ0, e+e- f1(1285)π+π-, e+e- π+π-, e+e- η, and e+e- η π+π- based on the same S-D mixing framework, and simultaneously reproduced their experimental cross section data. This work provides a unified framework to elucidate all observed -like structures near 2 GeV in the e+e- annihilation processes, and suggests that the S-D mixing effect may be crucial for understanding the mass spectrum and decay behaviors of the higher meson states.