Photon Emission from Nucleon-Nucleon Bremsstrahlung in Fermi-energy Heavy-Ion Collisions

TL;DR

This paper models photon emission from nucleon-nucleon Bremsstrahlung in Fermi-energy heavy-ion collisions, highlighting the dominant early-stage photon production and comparing theoretical results with experimental data.

Contribution

It introduces a quantum-field-theoretical emission rate combined with a coarse-grained transport model to analyze photon spectra in heavy-ion collisions.

Findings

Most hard photons originate from initial nucleon collisions.

Early-stage photon emission dominates over later stages.

Model results agree with experimental photon spectra.

Abstract

The emission of direct (hard and thermal) photons from nucleon-nucleon Bremsstrahlung in heavy-ion collisions at Fermi energies is analyzed. We utilize a photon emission rate based on a quantum-field-theoretical model together with nucleon distribution functions extracted from a coarse-graining method of transport model simulations. The latter accounts for off-equilibrium effects during the early stages of nuclear collisions primarily occurring in the beam direction while the transverse-momentum distributions are amenable to a thermal description. With this setup, we quantify the contributions from first-chance nucleon-nucleon collisions and the subsequent transition to a thermal source to the photon energy spectrum measured from Ca-Ca collisions at 35 A$\cdot$MeV bombarding energy. We find that most of the hard photons are produced in the initial stages of heavy-ion collisions from primordial collisions where nucleons move with the initial collective nuclear motion while the emission from the later stages plays a sub-dominant role. We compare our calculations to experimental measurements of a differential photon-energy spectrum from a collision system of similar size and beam energy, thereby including acceptance cuts as applied in the detectors.