Triple-X and beyond: hadronic systems of three and more X(3872)

Abstract

The X(3872) resonance has been conjectured to be a JPC = 1++ charm meson-antimeson two-body molecule. Meanwhile, there is no experimental evidence for larger, few-body compounds of multiple charm meson-antimeson pairs which would resemble larger molecules or nuclei. Here, we investigate such multi-meson states to the extent of what can be deduced theoretically from essentials of the interaction between uncharged D0 and D*0 mesons. From a molecular X(3872), we predict a 4X (4++) octamer with a binding energy B4X > 2.08\, MeV, assuming a D*0 D0 system close to the unitary limit (as suggested by the mass of the X(3872)). If we consider heavy-quark spin symmetry explicitly, the D*0 D*0 (2++) system is close to unitarity, too. In this case, we predict a bound 3X (3++) hexamer with B3X > 2.29\, MeV and a more deeply bound 4X octamer with B4X > 11.21\, MeV. These results exemplify with hadronic molecules a more general phenomenon of equal-mass two-species Bose systems comprised of equal number of either type: the emergence of unbound four- and six-boson clusters in the limit of a short-range two-body interaction which acts only between bosons of different species. Finally, we also study the conditions under which a 2X (2++) tetramer might form.