Theoretical investigation of the decay of the $N(2120)$ resonance to nucleon resonances near 1.7 GeV

TL;DR

This paper uses a theoretical quark model to analyze the decay of the $N(2120)$ resonance into lower-mass nucleon resonances near 1.7 GeV, providing predictions for future experimental investigations.

Contribution

It introduces a theoretical framework to study the decay of high-mass nucleon resonances into lower-mass states via three-pion photoproduction, which is novel in this context.

Findings

The decay $N(2120) o N(1675)\pi$ is dominant in the process.

The resonance contribution's cross section is around 1 μb, distinguishable from background.

Researching this decay experimentally is feasible.

Abstract

Background: Until now the knowledge about nucleon resonances with a mass higher than 2 GeV has been scarce. Huge amounts of experimental data of the multipion photoproduction have been accumulated, and more can be expected in the future in facilities such as JLab 12 GeV. It makes it possible to investigate the decay of a nucleon resonance into another nucleon resonance. Purpose: The possibility to research the decay of the $N(2120)$ to nucleon resonances near 1.7 GeV in the three-pion photoproduction will be explored to provide useful information for future experimental study. Method: The pion and radiative decay amplitudes of nucleon resonances are studied within the constituent quark model, which is used to calculate the couplings constants, especially for the decay of a nucleon resonance near 2.1 GeV to another nucleon resonance near 1.7 GeV. The three-pion photoproduction off the neutron target, i.e.,$\gamma n \to\pi^{-}\pi^{-}\Delta^{++}\to \pi^{-}\pi^{-}\pi^+ p$, is investigated based on the effective Lagrangian method with the coupling constant obtained form the decay amplitudes. Results: The resonance contribution with a state $N(^2P_M)\frac{3}{2}^{-}$ near 2.1 GeV decaying to a state $N(^4P_M)\frac{5}{2}^{-}$ near 1.7 GeV, i.\ e., $N(2120)\to N(1675)\pi$ is dominant in the process considered. The total cross section from the resonance contribution is at the order of 1 $\mu$b and can be easily distinguished from the background. Conclusions: Our results suggest it is practicable to research the decay of the $N(2120)$ to the $N(1675)$ in experiment.