# Low-energy $\eta$-nucleon interaction studied with $\eta$   photoproduction off the deuteron

**Authors:** S. X. Nakamura (1, 2), H. Kamano (3,4), T. Ishikawa (5,6) ((1) Osaka, Univ., (2) Univ. Cruzeiro do Sul, (3) KEK, (4) J-PARC, (5) ELPH, (6) Tohoku, Univ.)

arXiv: 1704.07029 · 2017-11-01

## TL;DR

This paper develops a reaction model for eta photoproduction off the deuteron to precisely determine the eta-nucleon scattering length and effective range, which are crucial for understanding low-energy eta-nucleon interactions.

## Contribution

The study introduces a specialized kinematic approach and a ratio observable that enhances sensitivity to eta-nucleon scattering parameters, enabling more accurate extraction from experimental data.

## Key findings

- The ratio R effectively constrains eta-nucleon scattering length and effective range.
- Predicted precision of about ±0.1 fm for Re[a_etaN] and ±0.5 fm for Re[r_etaN].
- The model emphasizes the importance of well-constrained elementary amplitudes.

## Abstract

We develop a reaction model for $\eta$ photoproduction off the deuteron ($\gamma d\to\eta pn$), and study the reaction at a special kinematics, where the photon beam energy is $\sim 0.94$ GeV and the scattered proton is detected at $\sim 0^\circ$, for the purpose of determining the $\eta$-nucleon scattering length ($a_{\eta N}$) and effective range ($r_{\eta N}$). In this kinematics, the $\eta$-nucleon elastic rescattering is significantly enhanced while other background mechanisms being suppressed. We show that a ratio $R$, the $\gamma d\to\eta pn$ cross section divided by the $\gamma p\to\eta p$ cross section convoluted with the proton momentum distribution in the deuteron, has a very good resolving power of $a_{\eta N}$ and $r_{\eta N}$. We conclude that the $R$ data with 5% error, binned in 1 MeV width of the $\eta$-neutron invariant mass, can determine ${\rm Re}[a_{\eta N}]$ (${\rm Re}[r_{\eta N}]$) at the precision of $\sim\pm$0.1 fm ($\sim\pm$0.5 fm), significantly narrowing down the previously estimated ranges of the parameters. To arrive at the conclusion, it is essential to use the $\gamma d\to\eta pn$ reaction model equipped with elementary amplitudes that are well constrained by $\pi N$ and $\gamma N$ reaction data through a sophisticated coupled-channels analysis. This result strongly motivates the Research Center for Electron Photon Science (ELPH) at Tohoku University to measure $R$.

## Full text

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## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1704.07029/full.md

## References

23 references — full list in the complete paper: https://tomesphere.com/paper/1704.07029/full.md

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Source: https://tomesphere.com/paper/1704.07029