Exploring theoretical uncertainties in the hydrodynamic description of relativistic heavy-ion collisions
Cheng Tang Chiu, Chun Shen
Abstract
We explore theoretical uncertainties in the hydrodynamic description of relativistic heavy-ion collisions by examining the full nonlinear causality conditions and quantifying the second-order transport coefficients' role on flow observables. The causality conditions impose physical constraints on the maximum allowed values of inverse Reynolds numbers during the hydrodynamic evolution. Including additional second-order gradient terms in the Denicol-Niemi-Moln\'ar-Rischke (DNMR) theory significantly shrinks the casual regions compared to those in the Israel-Stewart hydrodynamics. For $\mathrm{Au}+\mathrm{Au}$ collisions, we find the variations of flow observables are small with and without imposing the necessary causality conditions, suggesting a robust extraction of the quark-gluon plasma's transport coefficients in previous model-to-data comparisons. However, sizable sensitivity is present in small $p+\mathrm{Au}$ collisions, which poses challenges to study the small systems' collectivity.