Unravelling Pentaquarks with Born--Oppenheimer effective theory

Abstract

The hidden-charm pentaquark states Pcc(4312)+, Pcc(4380)+, Pcc(4440)+, and Pcc(4457)+, all with isospin I = 1/2, were discovered by the LHCb collaboration in the decay process b0 J/ p K-. Although their quantum numbers remain undetermined, these states have generated significant theoretical interest. We analyze their spectrum and decay patterns-including those of their spin partners-within the Born--Oppenheimer effective field theory (BOEFT), a framework grounded in QCD. At leading order in BOEFT, we identify these pentaquark states as bound states in BO potentials that exhibit at short-distance a repulsive octet behavior and a nonperturbative shift due to the adjoint baryons masses, while asymptotically approaching the cD threshold. We further incorporate O(1/mQ) spin-dependent corrections to compute pentaquark multiplet spin splittings. Based on the spectrum, semi-inclusive decay widths to J/ and ηc, and the decay width ratios to cD and cD*, we provide the first theoretical predictions for the adjoint baryon masses, which can be confirmed by future lattice QCD studies. Moreover, our analysis supports the quantum number assignments: JP = (1/2)- for Pcc(4312)+, (3/2)- for Pcc(4380)+, (1/2)- for Pcc(4457)+, and (3/2)- for Pcc(4440)+. We also present results for the lowest bottom pentaquarks.