Theoretical investigation of the molecular nature of Ds0*(2317) and Ds1(2460) and the possibility of observing the DDK bound state Kcc(4180) in inclusive e+e- cc collisions
Abstract
Searching for exotic multiquark states and elucidating their nature remains a central topic in understanding quantum chromodynamics--the underlying theory of the strong interaction. Two of the most studied such states are the charm-strange states Ds0*(2317) and Ds1(2460). In this letter, we show for the first time that their prompt production yields in inclusive e+e- cc collisions near s=10.6 GeV measured by the BABAR Collaboration, Y(Ds0*(2317)) and Y(Ds1(2460)), in particular the ratio R=Y(Ds0*(2317))/Y(Ds1(2460)), can be well explained in the molecular picture, which provide a highly nontrivial verification of their nature being DK/D*K molecules. On the contrary, treating them as pure cs P-wave states, the statistical model predicts a ratio R smaller than unity, in contrast with the experimental central value, though in agreement with it considering its relatively large uncertainty. In addition, we predict the production yield of the DDK three-body bound state, Kcc(4180), in e+e- cc collisions and find that it is within the reach of the ongoing Belle II experiment. The present study demonstrates the feasibility of a novel method to unravel the nature of exotic hadrons and the potential of electron-positron collisions in this regard.
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