Eta-mesic nuclei

TL;DR

This paper presents theoretical studies on the existence and properties of eta-mesic nuclei, emphasizing the importance of subthreshold eta-nucleon interactions and their impact on binding energies and experimental detectability.

Contribution

It introduces a self-consistent approach to modeling energy-dependent eta-nucleon interactions and assesses their effects on eta-mesic nuclear state predictions.

Findings

Subthreshold eta-nucleon amplitudes decrease rapidly below threshold.

Relatively small binding energies and widths of eta-nuclear states are predicted.

Subthreshold behavior is crucial for determining the existence and detectability of eta-mesic nuclei.

Abstract

In this contribution we report on theoretical studies of $\eta$ nuclear quasi-bound states in few- and many-body systems performed recently by the Jerusalem-Prague Collaboration [1-5]. Underlying energy-dependent $\eta N$ interactions are derived from coupled-channel models that incorporate the $N^*(1535)$ resonance. The role of self-consistent treatment of the strong energy dependence of subthreshold $\eta N$ amplitudes is discussed. Quite large downward energy shift together with rapid decrease of the $\eta N$ amplitudes below threshold result in relatively small binding energies and widths of the calculated $\eta$ nuclear bound states. We argue that the subthreshold behavior of $\eta N$ scattering amplitudes is crucial to conclude whether $\eta$ nuclear states exist, in which nuclei the $\eta$ meson could be bound and if the corresponding widths are small enough to allow detection of these $\eta$ nuclear states in experiment.