Fully strange tetra- and penta-quarks in a chiral quark model

Abstract

Motivated by the recently reported resonant structure X(2300), a strong candidate for a fully strange tetraquark with positive parity, we perform a systematic study of fully strange tetra- and penta-quark systems within a chiral quark model. Low-lying S-wave configurations of the ss s s and ssss s systems are investigated using the Gaussian Expansion Method (GEM) combined with the Complex Scaling Method (CSM), which allows for a unified treatment of bound, resonant, and scattering states. For tetraquarks, all possible configurations: meson-meson, diquark-antidiquark, and K-type structures, with complete color bases, are incorporated, while baryon-meson and diquark-diquark-antiquark configurations are considered for pentaquarks. Several weakly bound states and narrow resonances are identified in both sectors. In particular, a compact fully strange tetraquark with JP=1+ is found near 2.3\,GeV, providing a natural interpretation of the X(2300) resonance. Additional exotic states with dominant hidden-color and K-type components are predicted in the mass ranges 1.6-3.1 GeV for tetraquarks and 2.6-3.2 GeV for pentaquarks. The internal structure of these states is analyzed through their sizes, magnetic moments, and wave-function compositions, highlighting the essential role of channel coupling and exotic color configurations. Finally, promising two-body strong decay channels are proposed to facilitate future experimental searches.