Ratios of collective flow observables in high-energy isobar collisions are insensitive to final state interactions

TL;DR

This study demonstrates that ratios of flow observables in high-energy isobar collisions are robust against final state effects, making them reliable probes of initial nuclear structure differences.

Contribution

The paper shows that flow ratios are insensitive to final state interactions, highlighting their effectiveness in probing initial nuclear conditions.

Findings

Flow ratios change by over 50% with final state effects but remain unchanged in ratio form.

Ratios are independent of transverse momentum and hadron species.

Mean transverse momentum ratio is influenced by nuclear size and skin depth.

Abstract

The ratios of bulk observables, such as harmonic flow $v_2$ and $v_3$, between high-energy $^{96}$Ru+$^{96}$Ru and $^{96}$Zr+$^{96}$Zr collisions were recently argued to be a clean probe of the nuclear structure differences between $^{96}$Ru and $^{96}$Zr. Using a transport model simulation of isobar collisions, we quantify this claim from the dependence of the ratios $v_{2,\mathrm{Ru}}/v_{2,\mathrm{Zr}}$ and $v_{3,\mathrm{Ru}}/v_{3,\mathrm{Zr}}$ on various final state effects, such as the shear viscosity, hadronization and hadronic cascade. Although the $v_2$ and $v_3$ change by more than 50% when varying the final state effects, the ratios are unchanged. In addition, these ratios are independent of the transverse momentum $p_{\mathrm{T}}$ and hadron species, despite of up to a factor of two change in $v_n$. The ratio of mean transverse momentum $\left\langle p_{\mathrm{T}}\right\rangle$ is found to be controlled by the nuclear skin and nuclear radius, but is only slightly impacted by the final state effects. Therefore, these isobar ratios serve as a clean probe of the initial condition of the quark-gluon plasma, which in turn is controlled by the collective structure of the colliding nuclei.