Electromagnetic two-body currents of one- and two-pion range

TL;DR

This paper derives nuclear electromagnetic currents within an effective-field-theory framework including nucleons, deltas, and pions, and applies them to study neutron capture and nuclear magnetic moments, revealing significant cutoff dependence.

Contribution

It provides a detailed derivation of electromagnetic two-body currents up to N$^3$LO and applies them to nuclear processes, highlighting the cutoff sensitivity of theoretical predictions.

Findings

Underprediction of neutron-proton capture cross section by 11-38%

Significant cutoff dependence in theoretical results

Application of derived currents to A=2 and 3 nuclei magnetic moments

Abstract

Nuclear electromagnetic currents are derived in time-ordered perturbation theory within an effective-field-theory framework including explicit nucleons, $\Delta$ isobars, and pions up to one loop, or N$^3$LO. The currents obtained at N$^2$LO, {\it i.e.} ignoring loop corrections, are used in a study of neutron radiative captures on protons and deuterons at thermal energies, and of $A$=2 and 3 nuclei magnetic moments. The wave functions for $A$=2 are derived from solutions of the Schr\"odinger equation with the Argonne $v_{18}$ (AV18) or CD-Bonn (CDB) potentials, while those for $A$=3 are obtained with the hyperspherical-harmonics-expansion method from a realistic Hamiltonian including, in addition to the AV18 or CDB two-nucleon, also a three-nucleon potential. With the strengths of the $\Delta$-excitation currents occurring at N$^2$LO determined to reproduce the $n$-$p$ cross section and isovector combination of the trinucleon magnetic moments, we find that the cross section and photon circular polarization parameter, measured in $n$-$d$ and $\vec{n}$-$d$ processes, are underpredicted by theory, for example the cross section by (11--38)% as the cutoff is increased from 500 to 800 MeV. A complete analysis of the results, in particular their large cutoff dependence, is presented.