Higher-order correlations between different moments of two flow amplitudes in Pb$-$Pb collisions at $\sqrt{s_{\rm NN}}=5.02$ TeV

The correlations between different moments of two flow amplitudes, extracted with the recently developed asymmetric cumulants, are measured in Pb$-$Pb collisions at $\sqrt{s_{\rm NN}} = 5.02$ TeV recorded by the ALICE detector at the CERN Large Hadron Collider. The magnitudes of the measured observables show a dependence on the different moments as well as on the collision centrality, indicating the presence of non-linear response in all even moments up to the eighth. Furthermore, the higher-order asymmetric cumulants show different signatures than the symmetric and lower-order asymmetric cumulants. Comparisons with state-of-the-art event generators using two different parametrizations obtained from Bayesian optimization show differences between data and simulations in many of the studied observables, indicating a need for further tuning of the models behind those event generators. These results provide new and independent constraints on the initial conditions and transport properties of the system created in heavy-ion collisions.

 

Phys. Rev. C 108 (2023) 055203
HEP Data
e-Print: arXiv:2303.13414 | PDF | inSPIRE
CERN-EP-2023-047
Figure group

Figure 1

Centrality dependence of the different orders of $\AC_{a,b}(m,n)$ (left) and $\NAC_{a,b}(m,n)$ (right) for four pairs of indices ($a,b$) and three pairs of harmonics ($m,n$) in \PbPb collisions at \snn = 5.02 TeV. The mirror combinations of $\AC_{a,b}(m,n)$ (closed markers), i.e., $\AC_{b,a}(m,n)$, are indicated with open markers and similar color scheme. The statistical (systematic) uncertainties are shown with lines (boxes). The data points are shifted horizontally for visibility.

Figure 2

Centrality dependence of the different orders $a = 1,\ldots,3$ of $\NAC_{a,1}(2,3)$ (cyan closed circles) and $\NAC_{1,a}(2,3)$ (pink open squares) compared with the theoretical predictions from \trento+iEBE-VISHNU for the Duke 2019  and Jyv\"{a}skyl\"{a} 2022  parametrizations. Panel (d) shows a close-up of the results of $\NAC_{3,1}(2,3)$. The statistical uncertainties in the calculations are indicated by the thicknesses of the colored bands. The data points for $\NSC(2,3)$ are taken from Ref. .

Figure 3

Centrality dependence of the different orders $a = 1,\ldots,4$ of $\AC_{a,1}(2,4)$ (cyan closed circles) and $\AC_{1,a}(2,4)$ (pink open squares) compared with the theoretical predictions from \trento+iEBE-VISHNU for the Duke 2019  and Jyv\"{a}skyl\"{a} 2022  parametrizations. Panels (e) and (f) show a close-up of the results of $\AC_{1,3}(2,4)$ and $\AC_{1,4}(2,4)$, respectively. The statistical uncertainties in the calculations are indicated by the thicknesses of the colored bands.

Figure 4

Centrality dependence of the different orders $a = 1,\ldots,3$ of $\NAC_{a,1}(3,4)$ (cyan closed circles) and $\NAC_{1,a}(3,4)$ (pink open squares) compared with the theoretical predictions from \trento+iEBE-VISHNU for the Duke 2019  and Jyv\"{a}skyl\"{a} 2022  parametrizations. The statistical uncertainties in the calculations are indicated by the thicknesses of the colored bands. The data points for $\NSC(3,4)$ are taken from Ref. .

Figure 5

Centrality dependence of the different orders $a = 1,\ldots,3$ of $\NAC_{a,1}(m,n)$ and $\NAC_{1,a}(m,n)$ compared with the theoretical predictions from \trento+iEBE-VISHNU for the Duke 2019  and Jyv\"{a}skyl\"{a} 2022  parametrizations. The last point of $\NAC_{1,2}(2,4)$ and the results for $\NAC_{1,3}(2,3)$ are not shown for visibility purposes. The statistical uncertainties in the calculations are indicated by the thicknesses of the colored bands. The data points for $a = 1$ are taken from Ref. .

Figure 6

Values for $\chi^2$ test calculated between the data and two different model calculations for all ACs and NACs and all pairs of harmonics presented in this paper. The observables with large uncertainties are indicated with a grey filling, while an absence of observable (see Fig. \ref{fig:ALICEonly}) is shown with a white filling.

Figure A.1

Centrality dependence of the different orders $a = 1,\ldots,3$ of $\NAC_{a,1}(2,4)$ (cyan closed circles) and $\NAC_{1,a}(2,4)$ (pink open squares) compared with the theoretical predictions from \trento+iEBE-VISHNU for the Duke 2019  and Jyv\"{a}skyl\"{a} 2022  parametrizations. The statistical uncertainties in the calculations are indicated by the thicknesses of the colored bands. The data points for $\NSC(2,4)$ are taken from Ref. .