Pseudorapidity distribution and decorrelation of anisotropic flow within CLVisc hydrodynamics

Abstract

Studies of fluctuations and correlations of soft hadrons and hard and electromagnetic probes of the dense and strongly interacting medium require event-by-event hydrodynamic simulations of high-energy heavy-ion collisions that are computing intensive. We develop a (3+1)D viscous hydrodynamic model -- CLVisc that is parallelized on Graphics Processing Unit (GPU) using Open Computing Language (OpenCL) with 60 times performance increase for space-time evolution and more than 120 times for the Cooper-Frye particlization relative to that without GPU parallelization. The pseudo-rapidity dependence of anisotropic flow vn(η) are then computed in CLVisc with initial conditions given by the A Multi-Phase Transport (AMPT) model, with energy density fluctuations both in the transverse plane and along the longitudinal direction. Although the magnitude of vn(η) and the ratios between v2(η) and v3(η) are sensitive to the effective shear viscosity over entropy density ratio ηv/s, the shape of the vn(η) distributions in η do not depend on the value of ηv/s. The decorrelation of vn along the pseudo-rapidity direction due to the twist and fluctuation of the event-planes in the initial parton density distributions is also studied. The decorrelation observable rn(ηa, ηb) between vn\-ηa\ and vn\ηa\ with the auxiliary reference window ηb is found not sensitive to ηv/s when there is no initial fluid velocity. For small ηv/s, the initial fluid velocity from mini-jet partons introduces sizable splitting of rn(ηa, ηb) between the two reference rapidity windows ηb ∈ [3, 4] and ηb ∈ [4.4, 5.0], as has been observed in experiment. The implementation of CLVisc and guidelines on how to efficiently parallelize scientific programs on GPUs are also provided.