Experimental Study of Bremsstrahlung Gamma Ray Emission and Short-Range Correlations in $^{124}$Sn+$^{124}$Sn Collisions at 25 MeV/u

TL;DR

This study measures bremsstrahlung gamma rays in $^{124}$Sn+$^{124}$Sn collisions at 25 MeV/u to probe short-range correlations in nuclei, establishing a validated experimental framework for high-precision SRC analysis.

Contribution

It introduces a detailed experimental and analysis framework for extracting SRC information from bremsstrahlung gamma-ray emission in low-energy heavy-ion collisions.

Findings

High momentum tail fraction of $R_{HMT}=(20 \\pm 3)\%$ in $^{124}$Sn nuclei.

Validated background subtraction and analysis methods.

Demonstrated feasibility of studying nucleon SRCs with high precision.

Abstract

Short-range correlation (SRC) in nuclei refers to nucleons forming temporally correlated pairs in close proximity, giving rise to the high momentum of the nucleons beyond the Fermi surface. It has been reported that bremsstrahlung $\gamma$ production from neutron-proton process in heavy-ion reactions provides a potential probe to the SRC abundance in nuclei. In this paper, we present in detail the precision measurement of bremsstrahlung $\gamma$-rays in $\rm ^{124}Sn$+$\rm ^{124}Sn$ reactions at 25 MeV/u using the Compact Spectrometer for Heavy IoN Experiment (CSHINE). A comprehensive experimental and analysis framework is established to ensure the reliability and robustness of the extracted results. Background contributions are evaluated and subtracted using independent methods, and the consistency of the analysis is systematically validated. By comparing the experimental $\gamma$ spectrum with the Isospin-dependent Boltzmann-Uehling-Uhlenbeck simulations, the high momentum tail (HMT) fraction of $R_{\rm HMT}=(20 \pm 3)\%$ is derived in $^{124}$Sn nuclei. This work provides a detailed and validated experimental framework for extracting SRC information from bremsstrahlung $\gamma$-ray emission and demonstrates the feasibility of studying nucleon SRCs with high precision in low-energy heavy-ion collisions.