Abstract
A coupled-channel approach is applied to the charged tetraquark state ${T}_{cc}^{+}$ recently discovered by the LHCb Collaboration. The parameters of the interaction are fixed by a fit to the observed line shape in the three-body ${D}^{0}{D}^{0}{\ensuremath{\pi}}^{+}$ channel. Special attention is paid to the three-body dynamics in the ${T}_{cc}^{+}$ due to the finite life time of the ${D}^{*}$. An approach to the ${T}_{cc}^{+}$ is argued to be self-consistent only if both manifestations of the three-body dynamics, the pion exchange between the $D$ and ${D}^{*}$ mesons and the finite ${D}^{*}$ width, are taken into account simultaneously to ensure that three-body unitarity is preserved. This is especially important to precisely extract the pole position in the complex energy plane whose imaginary part is very sensitive to the details of the coupled-channel scheme employed. The ${D}^{0}{D}^{0}$ and ${D}^{0}{D}^{+}$ invariant mass distributions, predicted based on this analysis, are in good agreement with the LHCb data. The low-energy expansion of the ${D}^{*}D$ scattering amplitude is performed and the low-energy constants (the scattering length and effective range) are extracted. The compositeness parameter of the ${T}_{cc}^{+}$ is found to be close to unity, which implies that the ${T}_{cc}^{+}$ is a hadronic molecule generated by the interactions in the ${D}^{*+}{D}^{0}$ and ${D}^{*0}{D}^{+}$ channels. Employing heavy-quark spin symmetry, an isoscalar ${D}^{*}{D}^{*}$ molecular partner of the ${T}_{cc}^{+}$ with ${J}^{P}={1}^{+}$ is predicted under the assumption that the $D{D}^{*}\text{\ensuremath{-}}{D}^{*}{D}^{*}$ coupled-channel effects can be neglected.
Highlights
The quest of exotic hadrons with configurations beyond the naive quark-model picture of a pair of quark-antiquark for a meson and three quarks for a baryon has been a central issue in the study of nonperturbative quantum chromodynamics (QCD) for decades
In this work we employed a coupled-channel approach based on a nonrelativistic effective field theory to analyze the experimental data on the charged double-charm meson
The found pole can be associated with a bound state with respect to the two-body channels, with the reservation that its nomenclature formally depends on the way the three-body dynamics is introduced: it appears slightly shifted from the real axis if constant DÃ’s widths are included effectively or should be
Summary
The quest of exotic hadrons with configurations beyond the naive quark-model picture of a pair of quark-antiquark for a meson and three quarks for a baryon has been a central issue in the study of nonperturbative quantum chromodynamics (QCD) for decades. It resides extremely close to the threshold of a pair of neutral charmed mesons D0D Ã0 This exotic state is generally considered to be an excellent candidate for a. [18], the Weinberg Z-factor of the Tþcc, that is, the probability to find a compact component in the Tþcc wave function (a component other than DÃþD0), was computed using the scattering length and effective range, This implies properties of þ cc known so far indicate that this state is generally consistent with a molecular nature. We study in the þ cc state which are expected to have a strong impact on its properties This is because the DÃ’s are unstable and the corresponding three-body DDπ thresholds lie very close to and below the two-body DÃD ones, and the þ cc resides between the mentioned twoand threebody thresholds. Generalization to the light flavor SU(3) group is outlined in Appendix A and the effect of a finite width on the effective range is discussed in Appendix B
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