Confirming the existence of a new higher charmonium $\psi(4500)$ by the newly released data of $e^+e^- \to K^+K^- J/\psi$

TL;DR

This paper confirms a new higher charmonium state, $oldsymbol{ ext{Y}(4500)}$, observed in $e^+e^- o K^+K^- J/\psi$, supporting its identification as a $oldsymbol{ ext{5S-4D}}$ mixing charmonium state through reanalysis and theoretical calculations.

Contribution

The study reanalyzes the $e^+e^- o K^+K^- J/\psi$ data incorporating predicted charmonium states, resolving width discrepancies and supporting the $ ext{Y}(4500)$ as a higher charmonium $ ext{ψ}(4500)$.

Findings

The width deviation of $ ext{Y}(4500)$ is resolved by including $ ext{ψ}(4220)$ and $ ext{ψ}(4500)$.

The fitted branching ratio of $ ext{ψ}(4500) o K^+K^- J/\psi$ aligns with theoretical predictions.

Possible signals of the predicted $ ext{ψ}(4380)$ in the same process are discussed.

Abstract

Recently, the BESIII Collaboration published the Born cross section of $e^+e^- \to K^+K^- J/\psi$, in which a new vector enhancement structure $Y(4500)$ was observed for the first time. The mass of the $Y(4500)$ resonance structure is in good agreement with our previous prediction for a $5S$-$4D$ mixing charmonium candidate $\psi(4500)$, while the measured width is $2\sigma$ larger than the theoretical estimate. In this work, we reanalyzed the cross section of $e^+e^- \to K^+K^- J/\psi$ by introducing two theoretically predicted charmonium states $\psi(4220)$ and $\psi(4500)$ as intermediate resonances, and found that this width deviation problem can be resolved. Meanwhile, we found that the inclusion of two established charmonium states $\psi(4160)$ and $\psi(4415)$ can further improve the fit quality, with four sets of widely different solutions to $\Gamma_{e^+e^-} \mathcal{B}(\psi \to K^+K^- J/\psi)$. In order to better identify the properties of the $Y(4500)$, we calculated the charmonium hadronic transition to final states $K^+K^- J/\psi$ within the charmed meson loop mechanism, where the fitted branching ratio of $\psi(4500) \to K^+K^- J/\psi$ can be well explained by the theoretical calculation, further supporting the new enhancement structure around 4.5 GeV as a higher charmonium $\psi(4500)$ that we predicted. Finally, we also discussed the possible signal of another predicted charmonium candidate $\psi(4380)$ in $e^+e^- \to K^+K^- J/\psi$. These research results should be an important step in constructing the charmonium family and thoroughly solving the charmoniumlike $Y$ problem.