Deciphering the nature of PΣψs pentaquarks in the light of their electromagnetic multipole moments

Abstract

We calculate electromagnetic multipole moments of Σ-type strange hidden-charm pentaquarks PΣψs (isospin triplet Σ+,Σ0,Σ-) using QCD light-cone sum rules, with six (spin-1/2) and seven (spin-3/2) interpolating currents built from diquark-diquark-antiquark operators. We compute magnetic dipole μ for all channels and, for spin-3/2, electric quadrupole Q and magnetic octupole O moments (first computation), and give the first quark-flavor decomposition. Scalar diquark currents yield charm-dominated, flavor-insensitive moments (μ∈[-1.92,-1.21]μN for spin-1/2, |μ|1.2μN for spin-3/2), consistent with heavy-quark spin symmetry. Axial-vector diquark currents produce larger, flavor-sensitive moments with sign reversals governed by eu/ed=-2. For Q, scalar-diquark currents give oblate deformations (Q0≈-2.0×10-2 fm2) dominated by charm, while two-axial-vector-diquark currents predict prolate values up to Q0=+8.0×10-2 fm2, with sign reversal for [su][uc]c in two currents. Currents with scalar antiquark coupling yield a topology-independent octupole O≈-0.25×10-3 fm3, a lattice QCD benchmark. Comparison with constituent quark models identifies four discriminants: |μ|3μN in spin-1/2; sign of μ for [su][uc]c in spin-3/2; non-zero Q (vanishes in S-wave molecules); and the Q- O sign correlation, probing 1/mq weighting.