Higher fully-charmed tetraquarks: Radial excitations and P-wave states

TL;DR

This paper calculates the mass spectrum of higher excited fully-charmed tetraquarks, including radial and P-wave states, using a nonrelativistic quark model, and discusses potential experimental candidates like X(6900).

Contribution

It provides a systematic analysis of excited fully-charmed tetraquark states with detailed mass predictions and explores their possible experimental identification, including exotic quantum number states.

Findings

The $6_c-ar 6_c$ component is lower in energy than the $ar 3_c-3_c$ component.

Large mass splitting observed for $ ho$-mode excitations with different color configurations.

X(6900) could be a candidate for excited tetraquark states with specific quantum numbers.

Abstract

We systematically calculate the mass spectrum of the higher excited fully-charmed tetraquark $cc\bar c\bar c$ states including the S-wave radial excitations and the P-wave states with a nonrelativistic quark model. The quark model is composed of a vector one-gluon-exchange (OGE) and a scalar linear confinement interaction with the parameters determined by the charmonium spectrum. In the calculation, we consider both the $3_c-\bar 3_c$ and the $6_c-\bar{6}_c$ color representations. For the $cc\bar c\bar c $ state, the $6_c-\bar 6_c$ component is located lower than the $\bar 3_c-3_c$ one because of the stronger attractive interactions between the diquark and antidiquark. We focus on two excited modes and their properties for the P-wave tetraquarks. The mass splitting for the $\rho$-mode excitations with different color configurations is large. The low-lying $6_c-\bar 6_c$ $\rho$-mode component helps to explain the small mass gap between the ground S-wave and the P-wave tetraquark states. The recently observed $X(6900)$ state may be the candidate of the first radially excited tetraquarks with $J^{PC}=0^{++}$ or $2^{++}$, or the $1^{+-}$ or $2^{-+}$ P-wave states based on the mass spectrum. Moreover, the lowest $T_c$ states with the exotic $J^{PC}$ quantum numbers $0^{--}$ and $1^{-+}$ may decay into the P-wave $\eta_c J/\psi$ and di-$J/\psi$ modes, respectively. The future experimental search of these $T_c$ states will enrich the hadronic spectrum.