Charmed c+ baryon decays into light scalar mesons in the topological SU(3)f framework

Abstract

Using the topological-diagram approach based on SU(3) flavor symmetry, we investigate two-body c+ BS decays, where B denotes the final-state baryon and S refers to a light scalar meson, such as f0/f0(980), a0/a0(980), σ0/f0(500), or /K0*(700). Our analysis indicates that interpreting the light scalar mesons as tetraquark states provides a more consistent description of the currently available experimental data. In particular, this framework naturally accommodates the experimentally observed branching fraction B(c+ a0+), which exceeds predictions based solely on long-distance effects by an order of magnitude. Within the tetraquark scenario, we predict B(c+ + f0)=(4.9 1.9)× 10-2 and B(c+ p f0)=(3.6 1.4)× 10-3. Owing to f0-σ0 mixing, B(c+ + σ0) and B(c+ pσ0) are suppressed to the levels of 1× 10-3 and 5× 10-5, respectively. These modes therefore provide sensitive probes of the internal structure of the light scalar mesons. More generally, the remaining branching ratios of c+ B S are found to be comparable to those of c+ BM, where M denotes a pseudoscalar meson. Their predicted sizes suggest that these decay modes should be accessible to ongoing and near-future experimental studies at BESIII, Belle II, and LHCb.