Impact of event activity variable on the ratio of observables in isobar collisions

Abstract

The STAR isobar data of 96Ru+96Ru and 96Zr+96Zr collisions at sNN= 200 GeV show that ratios of observables (RO) such as the multiplicity distribution, p(Nch), and the harmonic flow, vn, deviate from unity, when presented as a function of centrality, c. These deviations have been attributed to the differences in the shape and radial profiles between 96Ru and 96Zr nuclei. In addition, the ratios RO(x) depend on the choice of the event activity variable x, which could be either Nch or centrality. We estimate the difference R between these two choices, based on the published p(Nch), as well as those from a multiphase transport (AMPT) model with varied nuclear structure parameters: nuclear radius (R0), surface diffuseness (a0), quadrupole deformation (β2), and octupole deformation (β3). In contrary to Rvn(c), Rvn(Nch) is nearly independent of the analysis approaches, suggesting that nonflow effects are better controlled by Nch than c. The ratios of observables sensitive to the chiral magnetic effect (CME) are also much closer to unity for x=Nch than x=c, indicating that the ratios calculated at the same Nch provide a better baseline for the non-CME background. According to the AMPT results, the dominant parameter for R is a0, while R0 and βn are only important in central collisions. The published p(Nch) is also used to estimate R pT for mean transverse momentum, which is non-negligible compared with R pT-1.