A systematic study of the $\pi^-/\pi^+$ ratio in heavy-ion collisions with the same neutron/proton ratio but different masses

TL;DR

This study uses transport model simulations to analyze how the $ pi$ ratio varies with system size and energy in heavy-ion collisions, revealing its potential as a probe for high-density nuclear symmetry energy.

Contribution

It systematically investigates the $ pi$ ratio in collisions with the same neutron/proton ratio but different masses, highlighting its sensitivity to the nuclear symmetry energy at high densities.

Findings

$ pi$ ratio increases with system size and decreasing beam energy.

The $ pi$ ratio effectively probes high-density symmetry energy.

Dynamical isospin fractionation influences the $ pi$ ratio.

Abstract

A systematic study of the $\pi^-/\pi^+$ ratio in heavy-ion collisions with the same neutron/proton ratio but different masses can help single out effects of the nuclear mean field on pion production. Based on simulations using the IBUU04 transport model, it is found that the $\pi^-$ / $\pi^+$ ratio in head-on collisions of $^{48}$Ca+$^{48}$Ca, $^{124}$Sn +$^{124}$Sn and $^{197}$Au+$^{197}$Au at beam energies from 0.25 to 0.6 \agev increases with increasing the system size or decreasing the beam energies. A comprehensive analysis of the dynamical isospin fractionation and the \rpi ratio as well as their time evolution and spatial distributions demonstrates clearly that the \rpi ratio is an effective probe of the high-density behavior of the nuclear symmetry energy.