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Applications of deep learning to relativistic hydrodynamics

Hengfeng Huang, Bo-Wen Xiao, Ziming Liu, Zeming Wu, Yadong Mu, Huichao Song

2021Physical Review Research20 citationsDOIOpen Access PDF

Abstract

Relativistic hydrodynamics is a powerful tool to simulate the evolution of the quark-gluon plasma in relativistic heavy-ion collisions. Using 10 000 initial and final profiles generated from (2+1)-dimensional relativistic hydrodynamics VISH2+1 with Monte Carlo Glauber (MC-Glauber) initial conditions, we train a deep neural network based on the stacked U-net, and use it to predict the final profiles associated with various initial conditions, including MC-Glauber, MC Kharzeev-Levin-Nardi (MC-KLN), a multiphase transport (AMPT) model, and the reduced thickness event-by-event nuclear topology (TRENTo) model. A comparison with the VISH2+1 results shows that the network predictions can nicely capture the magnitude and inhomogeneous structures of the final profiles, and creditably describe the related eccentricity distributions P( n ) (n = 2, 3, 4). These results indicate that a deep learning technique can capture the main features of the nonlinear evolution of hydrodynamics, showing its potential to largely accelerate the event-by-event simulations of relativistic hydrodynamics.

Topics & Concepts

GlauberPhysicsEvent (particle physics)Statistical physicsEccentricity (behavior)Nuclear physicsAstrophysicsScatteringQuantum mechanicsPolitical scienceLawHigh-Energy Particle Collisions ResearchParticle physics theoretical and experimental studiesQuantum Chromodynamics and Particle Interactions
Applications of deep learning to relativistic hydrodynamics | Litcius