Abstract
Motivated by the recent discovery of two new states in the $B^+\rightarrow D^+D^-K^+$ decay by the LHCb Collaboration, we study the $D\bar{D}K$ three-body system by solving the Schr\"odinger equation with the Gaussian Expansion Method. We show that the $D\bar{D}K$ system can bind with quantum numbers $I(J^P)=\frac{1}{2}(0^-)$ and a binding energy of $B_3(D\bar{D}K)=48.9^{+1.4}_{-2.4}$ MeV. It can decay into $J/\psi K$ and $D_s\bar{D}^*$ via triangle diagrams, yielding a partial decay width of about 1 MeV. As a result, if discovered, it will serve as a highly nontrivial check on the nature of the many exotic hadrons discovered so far and on non-perturbative QCD as well. Assuming heavy quark spin symmetry, the same formalism is applied to study the $D\bar{D}^*K$ system, which is shown to also bind with quantum numbers $I(J^P)=\frac{1}{2}(1^-)$ and a binding energy of $B_3(D\bar{D}^*K)\simeq 77.3^{+3.1}_{-6.6}$ MeV, consistent with the results of previous works.
Highlights
Starting from 2003 [1,2], many exotic hadronic states have been discovered experimentally
We employed the Gaussian expansion method to study the DD K system with the leading-order DK and D K potentials obtained in chiral perturbation theory and the DDpotential from the one boson exchange (OBE) model
We found the existence of a DD K bound state with a binding energy about 49 MeV
Summary
Starting from 2003 [1,2], many exotic hadronic states have been discovered experimentally. A DD K bound state cannot be found in the DþD−Kþ invariant mass spectrum, the recent experimental discovery indicates that a three-body DD K bound state, if it exists, could have been formed already and remains to be discovered at the current facilities. Motivated by these theoretical and experiment works, we study the strange hidden charm DD K system using the Gaussian Expansion Method (GEM) [44]. We find a DD K bound state as well as a DD ÃK bound state utilizing heavy quark spin symmetry
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