Abstract
Multi-particle correlation observables in the Relativistic Heavy Ion Collider small system scan are computed in a framework that contains both initial state momentum anisotropies from the Color Glass Condensate effective theory and final state hydrodynamic evolution. The initial state is computed using the IP-Glasma model and coupled to viscous relativistic hydrodynamic simulations, which are followed by microscopic hadronic transport. All parameters of the calculation were previously constrained using experimental data on Au+Au collisions at the same center of mass energy. We find that the qualitative features of the experimental data, such as the system and centrality dependence of the charged hadron momentum anisotropy, can only be reproduced when final state interactions are present. On the other hand, we also demonstrate that the details of the initial state are crucially important for the quantitative description of observables in the studied small systems, as neglecting the initial transverse flow profile or the initial shear stress tensor, which contain information on the momentum anisotropy from the Color Glass Condensate, has dramatic effects on the produced final state anisotropy. We further show that the initial state momentum anisotropy is correlated with the observed elliptic flow in all small systems, with the effect increasing with decreasing multiplicity. We identify the precise measurement of v2 in d+Au and Au+Au collisions at RHIC energy at the same multiplicity as a means to reveal effects of the initial state momentum anisotropy.
Highlights
The origins of azimuthal anisotropies in the produced hadron momentum distributions observed in high energy collisions involving protons or other small nuclei at the Relativistic Heavy Ion Collider (RHIC) and the Large Hadron Collider (LHC) have been under strong debate [1, 2]
We allow for the comparison to experimental data by computing hadronic final states instead of studying parton spectra, and second, we quantify how strongly the Color Glass Condensate (CGC) initial state momentum anisotropy can affect experimental observables if final state interactions are described by realistic hydrodynamic simulations that were constrained by heavy ion data
Previous calculations involving the IP-Glasma initial state coupled to a hydrodynamic description of the final state evolution [41,42,43] in principle contain information on both CGC initial state and geometry driven final state sources of correlations
Summary
When the medium temperature drops to the switching temperature Tsw = 145 MeV, the fluid is converted to particles by first computing the particle spectra according to the Cooper-Frye formula [63], using equilibrium distributions f0 with viscous corrections δf , given in [64,65,66] for shear and bulk viscous terms. From these non-equilibrium distribution functions f = f0 + δf , we sample particles on the switching surface that undergo the microscopic transport processes of UrQMD [45, 46]. We present both the gluon multiplicity distributions (folded with a Poisson distribution to estimate the effect of (grand canonical) sampling on the
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