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

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), however, have remained inconclusive, because the non-CME background contributions are not well understood. Experimentally, the γ correlators have been measured with respect to the second-order (2) and the third-order (3) symmetry planes, defined as γ112 and γ123, respectively. The expectation was that with a proper normalization, γ123 would provide a data-driven estimate for the background contributions in γ112. In this work, we calculate different harmonics of the γ 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 and γ123, quantified by 112 and 123, respectively. Furthermore, we test another correlator, γ132, within AMPT, and discuss the relation between different γ correlators.