Decorrelation of anisotropic flows along the longitudinal direction

TL;DR

This study investigates how initial longitudinal fluctuations in heavy-ion collisions cause decorrelation of anisotropic flows, using a (3+1)D hydrodynamic model, and compares results with experimental data to understand the underlying physics.

Contribution

It introduces a detailed analysis of longitudinal flow decorrelation using a (3+1)D hydrodynamic model with initial conditions from AMPT, highlighting the roles of linear twist and fluctuations.

Findings

Decorrelation originates from spatial longitudinal fluctuations.

Agreement with CMS data suggests initial string-like mechanisms.

Stronger decorrelation predicted at lower collision energies.

Abstract

The initial energy density distribution and fluctuation in the transverse direction lead to anisotropic flows of final hadrons through collective expansion in high-energy heavy-ion collisions. Fluctuations along the longitudinal direction, on the other hand, can result in decorrelation of anisotropic flows in different regions of pseudo rapidity ($\eta$). Decorrelation of the $2$nd and $3$rd order anisotropic flows with different $\eta$ gaps for final charged hadrons in high-energy heavy-ion collisions is studied in an event-by-event (3+1)D ideal hydrodynamic model with fully fluctuating initial conditions from A Multi-Phase Transport (AMPT) model. The decorrelation of anisotropic flows of final hadrons with large $\eta$ gaps are found to originate from the spatial decorrelation along the longitudinal direction in the AMPT initial conditions through hydrodynamic evolution. The decorrelation is found to consist of both a linear twist and random fluctuation of the event-plane angles. The agreement between our results and recent CMS data in most centralities suggests that the string-like mechanism of initial parton production in AMPT model captures the initial longitudinal fluctuation that is responsible for the measured decorrelation of anisotropic flows in Pb+Pb collisions at LHC. Our predictions for Au+Au collisions at the highest RHIC energy show stronger longitudinal decorrelation, indicating larger longitudinal fluctuations at lower beam energies. Our study also calls into question some of the current experimental methods for measuring anisotropic flows and extraction of transport coefficients through comparisons to hydrodynamic simulations that do not include longitudinal fluctuations.