Compact csss Tetraquarks in the Charm--Strange Sector: Mass Spectra, Rearrangement Decays and Regge Trajectories with Ds Threshold Inputs

Abstract

This work presents a spectroscopy-focused study of the compact open-charm, multi-strange tetraquark configuration \(csss\), modeled as an axial diquark-antidiquark system \([cs][ss]\). The conventional \(Ds\) meson spectrum is retained as a calibration sector for the model parameters and as a reference for the dominant two-meson thresholds; however, the primary emphasis is placed on the mass spectrum, threshold structure, rearrangement decay mechanisms, and Regge systematics of the \(csss\) tetraquark. The spectrum is computed within a Cornell-potential framework using both semi-relativistic and non-relativistic treatments, with the \(3-3\) and \(6-6\) color configurations analyzed separately. Owing to the presence of two identical strange antiquarks, Pauli symmetry imposes restrictions on the \([ss]\) antidiquark, favoring axial-vector building blocks as the natural low-lying degrees of freedom for the \(JP=0+,1+,2+\) tetraquark multiplet. The strong-decay sector is formulated in terms of the rearrangement topology \(csss→(cs)(ss)\), with the \(Ds(*)η\), \(Ds(*)η'\), and \(Ds(*)ϕ\) modes identified through spin-color Fierz recoupling and normalized using two-point and three-point QCD-sum-rule amplitudes. Orbital and radial Regge trajectories are constructed to characterize the excitation patterns of the compact tetraquark and to benchmark them against the calibrated \(Ds\) spectrum. This framework provides a dedicated phenomenological basis for identifying \(csss\) candidates in hidden-strangeness open-charm final states.