Threshold cusp effects to measure masses of radiatively decaying hadrons: The Bs0* mass from the Υϕ spectrum

Abstract

Hadrons that decay predominantly into final states containing photons are notoriously difficult to detect at hadron colliders. Prominent examples are the yet-unobserved Bs0* and Bs1, the bottom partners of the Ds0*(2317) and Ds1(2460), which are expected to exhibit exotic properties deviating from the conventional quark-model predictions of b s mesons. We propose a general, model-independent method to overcome this problem: when the target hadron has an attractive S-wave interaction with a companion hadron of precisely known mass, the line shape of a suitable final state develops a cusp at the pair threshold, or a peak just below it if the attraction binds, so that subtracting the companion mass returns the target mass, up to the binding energy in the latter case. As a proof of concept, a leading-order particle-dimer calculation of the D Ds K three-body system reproduces the X(4274) structure in the LHCb J/ψϕ distribution extracted from B K J/ψϕ, as a Ds0* Ds threshold cusp driven by a nearby virtual-state pole, yielding mDs0*=(23226) MeV in agreement with its measured value and favoring JPC=0-+ for the X(4274). Transferring the elastic three-body interaction to the bottom sector, we predict an analogous structure at the Bs0* Bs threshold near 11.09 GeV, making the Υϕ invariant-mass distribution at the LHC a clean probe of the Bs0* mass.