Signatures of the Ω(2012)- state in Ξ* K Correlation Functions

Abstract

We investigate the Ω(2012) resonance in the strangeness S=-3 sector within a coupled-channel chiral unitary approach and present the first quantitative predictions for femtoscopic correlation functions directly sensitive to its dynamics. The Ω(2012) is dynamically generated as a quasi-bound Ξ K-Ωη molecular state, with its coupling to the ΞK channel driven by d-wave transitions. Model parameters are constrained by the measured mass, width, and the Belle determination of the branching fraction RΞ KπΞ K, yielding MΩ(2012)=(2012.530.73) MeV and ΓΩ(2012)=(4.050.13) MeV. Within this framework, we compute the femtoscopic correlation functions of the Ξ0K-, Ξ- K0, and Ω-η systems. The Ξ K correlation functions exhibit pronounced near-threshold structures that arise from the proximity of the Ω(2012) pole, demonstrating an exceptional sensitivity to its position and coupled-channel composition. In particular, the Ξ0K- correlation function is identified as a clean and highly selective probe of the Ω(2012) resonance. These results establish femtoscopic correlation measurements as powerful tools for extracting resonance properties beyond conventional invariant-mass analyses and provide concrete theoretical benchmarks for upcoming experimental studies aimed at elucidating the molecular nature of the Ω(2012).