Decays of doubly charmed meson molecules

TL;DR

This paper predicts and analyzes the decay properties of doubly charmed meson molecules near specific thresholds, providing theoretical decay widths and identifying their dominant decay modes.

Contribution

It introduces the calculation of decay widths and modes for newly predicted doubly charmed meson molecules with specific quantum numbers, expanding understanding of their observable signatures.

Findings

Decay width of 44 MeV for non-strange doubly charmed molecule

Decay width of 24 MeV for doubly charm-strange molecule

Main decay modes include $DD_{(s)} o D_{(s)}D^*$, $DD_{(s)} o DD_{(s)} ho$, and radiative decays

Abstract

Several observed states close to the $D\bar{D}^*$ and $D^*_{(s)}\bar{D}^*_{(s)}$ thresholds, as the X(3872) and some XYZ particles can be described in terms of a two-meson molecule. Furthermore, doubly charmed states are also predicted. These new states are near the $D^*D^*$ and $D^*D^*_s$ thresholds, % Therefore, if the previous XYZ are molecules, then, there should be doubly charmed mesons with $J^P=1^+$ around the $D^*D^*$ threshold. %For this reason, it is important to evaluate observables related to them. Because of the spin$=1$, they do not decay into $DD$. In this article we compute decays to $DD^*$ and radiative decays of doubly charmed meson molecules into $DD_{(s)}\gamma$. and have spin-parity $J^P=1^+$. Their natural decay modes are $D_{(s)}D^*$, $DD_{(s)}\pi$ and $DD_{(s)}\gamma$ and $D^*D_{(s)}\gamma$. We evaluate the widths of these states, named here as $R_{cc}(3970)$ and $S_{cc}(4100)$, and obtain 44 MeV for the non-strangeness, and 24 MeV for the doubly charm-strange state. Essentially, the decay modes are $DD_{(s)}\pi$ and $DD_{(s)}\gamma$, being the $D\pi$ and $D\gamma$ emitted by one of the $D^*$ meson which forms the molecule.