On the mechanism of T4c(6900) tetraquark production

We discuss the production mechanism of a new state, a putative fully charm tetraquark, observed recently by the LHCb at M = 6.9 GeV in the J/phi J/phi channel. Both single parton scattering (SPS) and double parton scattering (DPS) mechanisms are considered. We calculate the distribution in the invariant mass of the four-quark system M-4c for SPS and DPS production of cc (c) over bar(c) over bar in the k(T)-factorization approach with modern unintegrated gluon distribution functions (UGDFs). The so-calculated contribution of DPS is almost two orders of magnitude larger than the SPS one, but the tetraquark formation mechanism is unknown at present. Imposing a mass window around the resonance position we calculate the corresponding distribution in p(t,4c) - the potential tetraquark transverse momentum. The cross section for the J/phi J/phi continuum is calculated in addition, again including SPS (box diagrams) and DPS contributions which are of similar size. The formation probability is estimated trying to reproduce the LHCb signal-to-background ratio. The calculation of the SPS gg -> T-4c(6900) fusion mechanism is performed in the k(T)-factorization approach assuming different spin scenarios (0(+) and 0(-)). The 0(+) assignment is preferred over the 0(-) one by the comparison of the transverse momentum distribution of signal and background with the LHCb preliminary data assuming the SPS mechanism dominance. There is no reliable approach for the DPS formation mechanism of tetraquarks at present as this is a complicated multi-body problem. (C) 2020 The Authors. Published by Elsevier B.V. This is an open access article under the CC BY license.

Automated summary

The study discusses the production mechanism of a putative fully charm tetraquark observed by LHCb recently, considering both single parton scattering (SPS) and double parton scattering (DPS) mechanisms. Calculations show that the contribution of DPS is almost two orders of magnitude larger than SPS, but the tetraquark formation mechanism remains unknown. The preferred spin scenario is 0(+) over 0(-) based on comparison with LHCb preliminary data.