Structure of the $\Lambda(1405)$ and the $K^-d\rightarrow\pi\Sigma n$ reaction

The $\Lambda(1405)$ resonance production reaction is investigated within the framework of the coupled-channels Alt-Grassberger-Sandhas (AGS) equations. We perform full three-body calculations for the $\bar{K}NN-\pi YN$ amplitudes on the physical real energy axis and investigate how the signature of the $\Lambda(1405)$ appears in the cross sections of the $K^-d\rightarrow \pi\Sigma n$ reactions, also in view of the planned E31 experiment at J-PARC. Two types of meson-baryon interaction models are considered: an energy-dependent interaction based on chiral $SU(3)$ effective field theory, and an energy-independent version that has been used repeatedly in phenomenological approaches. These two models have different off-shell properties that imply correspondingly different behavior in the three-body system. We investigate how these features show up in differential cross sections of $K^- d\rightarrow \pi\Sigma n$ reactions. Characteristic patterns distinguishing between the two models are found in the invariant mass spectrum of the final $\pi\Sigma$ state. The $K^-d\rightarrow \pi\Sigma n$ reaction, with different ($\pi^{\pm}\Sigma^{\mp}$ and $\pi^{0}\Sigma^{0}$) charge combinations in the final state, is thus demonstrated to be a useful tool for investigating the subthreshold behavior of the $\bar{K}N$ interaction.