Radiative decays of dynamically generated pentaquarks in the chiral unitary approach: the Pc(4457) Pc(4312)\,γ transition

Abstract

We study the radiative decay of dynamically generated pentaquarks and apply the formalism to the transition Pc(4457)(3/2-) Pc(4312)(1/2-)γ. Both states are treated as S-wave hadronic molecules generated in the chiral unitary approach with heavy-quark spin symmetry and the local hidden gauge interaction. The photon therefore couples to the meson-baryon components of the two poles. The calculation combines the strong coupling residues of the coupled-channel solution, heavy-quark spin symmetry for the electromagnetic vertices, and a transverse assembly of the M1 triangle loops. A complete calculation gives nineteen triangle loops. We reduce each loop to a single numerical quadrature and give the closed analytic form. The electromagnetic vertices that are not fixed by data are estimated with the naive-quark model and heavy-quark spin symmetry. We normalize the main D*Dγ coupling to D*0 D0γ and test the same convention with J/ψηcγ. The central width is 6.7, with a conservative range of about 2 to 9. This radiative decay process is a pure M1 transition with photon energy 143. The D*0 D0γ loop gives the leading contribution. The near-threshold D*Λc loop gives the main correction. A soft Gaussian form-factor on the leading diagram reduces the width to about 2, compatible with earlier molecular results, and decreases the full width to about 4. The coherent result is sensitive to the relative residue phases in the coupled-channel convention. We also estimate the cascade rate for Λb0 J/ψ\,p\,K-γ and discuss how the line can be searched for. The pure M1 content, the ratio to the Pc(4440) radiative decay, and the binding-energy dependence of the width are proposed as tests of the molecular nature.