Radiative decays of the heavy-quark-spin molecular partner of Tcc+

Abstract

With the assumptions that the Tcc+ discovered at LHCb is a D*D hadronic molecule, using a nonrelativistic effective field theory we calculate the radiative partial widths of Tcc* D*Dγ with Tcc* being a D*D* shallow bound state and the heavy-quark-spin partner of Tcc+. The I=0 D*D rescattering effect with the Tcc pole is taken into account. The results show that the isoscalar D D rescattering can increase the tree-level decay width of Tcc +→ D*+D0γ by about 50\%, while decrease that of Tcc +→ D*0D+γ by a similar amount. The two-body partial decay widths of the Tcc*+ into Tcc+γ and Tcc+π0 are also calculated, and the results are about 6~keV and 3~keV, respectively. Considering that the D* needs to be reconstructed from the Dπ or Dγ final state in an experimental measurement, the four-body partial widths of the Tcc*+ into DDγγ and DDπγ are explicitly calculated, and we find that the interference effect between different intermediate D*Dγ states is small. The total radiative decay width of the Tcc* is predicted to be about 24~keV. Adding the hadronic decay widths of Tcc* D*Dπ, the total width of the Tcc* is finally predicted to be (652) keV.