Nucleon and $\Delta$ resonances in $\gamma n \to K^+\Sigma^-$ photoproduction

TL;DR

This paper analyzes the reaction mechanisms of gamma neutron to K+ Sigma- photoproduction using an effective Lagrangian approach, identifying key resonance contributions and exchange processes across different energy regions.

Contribution

It introduces a comprehensive model including various exchange channels and resonance parameters to describe experimental data on gamma neutron to K+ Sigma- reactions.

Findings

Resonance exchanges like N(1710), N(1880), N(1900), and Delta(1920) dominate at lower energies.

t-channel K* exchange is crucial at forward angles at higher energies.

The model successfully describes available experimental data.

Abstract

The most recent data on beam asymmetries, $\Sigma$, and beam-target asymmetries, $E$, from the CLAS Collaboration, together with the previous data on differential cross sections and beam asymmetries from the CLAS and LEPS Collaborations, for the $\gamma n \to K^+\Sigma^-$ reaction are studied based on an effective Lagrangian approach in the tree-level Born approximation. The $t$-channel $K$ and $K^\ast(892)$ exchanges, the $u$-channel $\Sigma$ exchange, the interaction current, and the exchanges of $N$, $\Delta$, and their excited states in the $s$ channel are considered in constructing the reaction amplitudes to describe the available experimental data. The reaction mechanisms of $\gamma n \to K^+\Sigma^-$ are analyzed, and the associated resonances' parameters are extracted. The numerical results show that the $\Delta$ exchange and the $N(1710)1/2^+$, $N(1880)1/2^+$, $N(1900)3/2^+$, and $\Delta(1920)3/2^+$ resonance exchanges in the $s$-channel dominate the $\gamma n \to K^+\Sigma^-$ reaction in the lower energy region, and the $t$-channel $K^\ast(892)$ exchange plays a crucial role at forward angles in the higher energy region.