English

Background evaluations for the chiral magnetic effect with normalized correlators using a multiphase transport model

High Energy Physics - Phenomenology 2020-06-24 v1 High Energy Physics - Experiment Nuclear Experiment

Abstract

The chiral magnetic effect (CME) induces an electric charge separation in a chiral medium along the magnetic field that is mostly produced by spectator protons in heavy-ion collisions. The experimental searches for the CME, based on the charge-dependent angular correlations (γ\gamma), however, have remained inconclusive, because the non-CME background contributions are not well understood. Experimentally, the γ\gamma correlators have been measured with respect to the second-order (Ψ2\Psi_{2}) and the third-order (Ψ3\Psi_{3}) symmetry planes, defined as γ112\gamma_{112} and γ123\gamma_{123}, respectively. The expectation was that with a proper normalization, γ123\gamma_{123} would provide a data-driven estimate for the background contributions in γ112\gamma_{112}. In this work, we calculate different harmonics of the γ\gamma correlators using a charge-conserving version of a multiphase transport (AMPT) model to examine the validity of the said assumption. We find that the pure-background AMPT simulations do not yield an equality in the normalized γ112\gamma_{112} and γ123\gamma_{123}, quantified by κ112\kappa_{112} and κ123\kappa_{123}, respectively. Furthermore, we test another correlator, γ132\gamma_{132}, within AMPT, and discuss the relation between different γ\gamma correlators.

Keywords

Cite

@article{arxiv.1909.04083,
  title  = {Background evaluations for the chiral magnetic effect with normalized correlators using a multiphase transport model},
  author = {Subikash Choudhury and Gang Wang and Wanbing He and Yu Hu and Huan Zhong Huang},
  journal= {arXiv preprint arXiv:1909.04083},
  year   = {2020}
}

Comments

8 pages, 6 figures

R2 v1 2026-06-23T11:10:12.882Z