Probing the long-range structure of the Tcc+ with the strong and electromagnetic decays

Abstract

Very recently, the LHCb Collaboration reported the doubly charmed tetraquark state Tcc+ below the D*+D0 threshold about 273 keV. As a very near-threshold state, its long-distance structure is very important. In the molecular scheme, we relate the coupling constants of Tcc+ with D*0D+ and D*+D0 to its binding energy and mixing angle of two components with a coupled-channel effective field theory. With the coupling constants, we investigate the kinetically allowed strong decays Tcc+ D0D0π+, Tcc+ D+D0π0 and radiative decays D+D0 γ. Our results show that the decay width of Tcc+ D0D0π+ is the largest one, which is just the experimental observation channel. Our theoretical total strong and radiative widths are in favor of the Tcc+ as a |D*+D0 dominated bound state. The total strong and radiative width in the single channel limit and isospin singlet limit are given as 59.7+4.6-4.4 keV and 46.7+2.7-2.9 keV, respectively. Our calculation is cutoff-independent and without prior isospin assignment. The absolute partial widths and ratios of the different decay channels can be used to test the structure of Tcc+ state when the updated experimental results are available.