(3+1)D event-by-event pre-equilibrium dynamics in heavy-ion collisions

TL;DR

This paper extends the KoMPoST framework to (3+1)D, enabling more accurate modeling of early-time, non-boost-invariant dynamics in heavy-ion collisions, and assesses the transition to hydrodynamics.

Contribution

It introduces a (3+1)D response function extension to KoMPoST for non-boost-invariant initial conditions in heavy-ion collisions.

Findings

Extended KoMPoST to include longitudinal fluctuations.

Compared shear-stress tensor from kinetic theory and hydrodynamics.

Simulated full spacetime evolution with sensitivity analysis.

Abstract

So far a major source of uncertainty in the study of heavy-ion collisions arises from the early time dynamics which includes initial state and pre-equilibrium dynamics. The state-of-the-art framework, KoMPoST, employs non-equilibrium Green's functions to propagate the initial energy-momentum tensor to the hydrodynamic phase, yet currently only treats transverse plane dynamics under boost-invariant conditions. In this work, we extend KoMPoST to include non-boost-invariant responses to initial conditions, essential for accurately capturing the longitudinal structures observed in heavy-ion collisions. Non-boost-invariant fluctuations on top of a homogeneous background are evolved using (3+1)D response functions calculated in kinetic theory. To assess kinetic theory's transition towards hydrodynamic evolution, we systematically compare the out-of-equilibrium shear-stress tensor from KoMPoST-3D with estimates based on Navier-Stokes hydrodynamics. Subsequently, a comprehensive (3+1)D framework, McDIPPER+KoMPoST-3D+CLVisc+SMASH, is utilized to simulate the complete spacetime evolution of heavy-ion collisions. The sensitivity of key observables, including longitudinal structure of anisotropic flow, to variations in the hydrodynamic initialization time is thoroughly investigated.