New insight into nd→ 3Hγ process at thermal energy with pionless effective field theory

Abstract

We take a new look at the neutron radiative capture by a deuteron at thermal energy with the pionless effective field theory (EFT(π\!\!\!/)) approach. We present in detail the calculation of nd→ 3Hγ amplitudes for incoming doublet and quartet channels leading to the formation of a triton fully in the projection method based on the cluster-configuration space approach. In the present work, we consider all possible one-body and two-body photon interaction diagrams. In fact, additional diagrams that make significant changes in the results of the calculation of the total cross section in the nd→ 3Hγ process are included in this study. The properly normalized triton wave function is calculated and taken into consideration. We compare the cross section of the dominant magnetic M1-transition of nd→ 3Hγ up to next-to-next-to-leading order N2LO with the results of the previous model-dependent theoretical calculations and experimental data. The more acceptable results for cross section σ(2)tot=0.297\;(LO)+0.124\;(NLO)+0.048\;(N2LO)=[0.4690.033]\:mb show order by order convergence and cutoff independence. No three-body currents are needed to renormalize observables up to N2LO in this process.