Abstract
The lineshapes of specific production experiments of the exotic state such as $X(3872)$ with $J^{PC}=1^{++}$ quantum numbers involving triangle singularities have been found to become highly sensitive to the binding energy of weakly bound states, thus offering in principle the opportunity of benchmark determinations. We critically analyze recent proposals to extract accurately and precisely the $X(3872)$ mass, which overlook an important physical effect by regarding their corresponding production lineshapes as a sharp mass distribution and, thus, neglecting the influence of initial nearby continuum states in the $1^{++}$ channel. The inclusion of these states implies an effective cancellation mechanism which operates at the current and finite experimental resolution of the detectors so that one cannot distinguish between the $1^{++}$ bound-state and nearby $D \bar D^*$ continuum states with the same quantum numbers. In particular, we show that the lineshape for resolutions above 1 MeV becomes rather insensitive to the binding energy unless high statistics is considered. The very existence of the observed bumps is a mere consequence of short distance correlated $\bar D D^*$ pairs, bound or unbound. The cancellation also provides a natural explanation for a recent study reporting missing but unknown decay channels in an absolute branching ratio global analysis of the $X(3872)$.
Highlights
The quest for the hadronic spectrum has been a major goal in particle physics over the past 70 years, which has been marked by predicting and reporting the observed states and their properties in the PDG
We have found in previous works that this has implications to count Xð3872Þ degrees of freedom at finite temperatures of relevance in relativistic heavy ions collisions [14,15] and ultrahigh energies pp prompt Xð3872Þ production at finite pT and midrapidity [16]
II we review the hadronic density of states and its theoretical and experimental limitations as it will be a key element of our analysis
Summary
The quest for the hadronic spectrum has been a major goal in particle physics over the past 70 years, which has been marked by predicting and reporting the observed states and their properties in the PDG (see e.g., [1] for the latest edition upcoming). Before 2003, this task has mostly been phenomenologically supported by a nonrelativistic quark model pattern and its given symmetry multiplets suggested by the underlying qqand qqq composition for mesons and baryons, respectively This nonrigorous but effective link has been a quite useful and extremely relevant guidance, because, currently, it is theoretically unknown how many states should occur below a given maximal energy or if the full set of recorded states are incomplete or redundant [2]. As it is most often the case for hadronic resonances, we do not detect directly the reported particle through its track but only in terms of its decaying products so that the corresponding invariant mass.
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