Probing the Core of Nuclear Structure through the $\pi N$ Scattering at an Electron-Positron Collider

TL;DR

This paper proposes using meson scattering at electron-positron colliders to study short-range correlations in nuclear structure, filling a research gap and providing measurable signatures of off-shell nucleons.

Contribution

It introduces a novel method to probe SRCs via meson scattering at electron-positron colliders, leveraging existing experimental setups like BESIII.

Findings

Estimated 10^4 events at BESIII support feasibility.

Signatures include missing energy and shifted effective mass.

Higher luminosity colliders will significantly increase data.

Abstract

Short-range correlation pairs (SRCs) -- core of nuclear structure, composed of highly off-shell nucleons -- are mostly studied via electron-nucleon scattering, leaving a gap in meson-based probes. We propose probing SRC off-shell nucleons via quasielastic $\pi^+$-bound proton scattering ($\pi^+ p \to \pi^+ p$) at electron-positron colliders, of which the beryllium-based ($^{9}$Be) beam pipe of the BESIII experiment operating at BEPCII, addresses a key gap and enables meson-beam investigations of SRCs. We point out that off-shellness of SRC nucleons yields measurable signatures: accumulated missing energy ($\sim0.1$\,GeV), shifted proton effective mass (0.7-0.8\,GeV), and cross-section differences from free scattering or with only Fermi motion. As an estimate, we find that BESIII's high luminosity and $\pi^+$ yield support $\sim10^4$ scattering events, while STCF ($50\times$ higher luminosity) will greatly enhance this number. This first meson-beam SRC study at an electron-positron collider fills $^{9}$Be research gaps and advances understanding of nuclear structure core and nonperturbative QCD.