Experimental review on the chiral magnetic effect in relativistic heavy ion collisions

TL;DR

This paper reviews the current experimental efforts to detect the chiral magnetic effect in relativistic heavy ion collisions, discussing challenges, techniques, and future prospects in identifying this quantum chromodynamics phenomenon.

Contribution

It provides a comprehensive overview of experimental methods, background mitigation strategies, and the status of CME searches in high-energy nuclear collisions.

Findings

No conclusive evidence for CME yet

Background contributions complicate CME detection

Various experimental approaches have different strengths and limitations

Abstract

The chiral magnetic effect (CME) refers to a predicted phenomena in quantum chromodynamics that manifests as a charge separation along an external magnetic field, driven by an imbalance of quark chirality. Searches for the CME has been carried out by azimuthal particle correlations in relativistic heavy ion collisions where such a chirality imbalance is anticipated and a strong magnetic field is created in the initial stage. No conclusive experimental evidence on the CME has been established so far because of large background contributions to azimuthal correlation observables. We review the status of the experimental search for the CME, covering the observables used, the techniques to mitigate backgrounds, and the strengths and limitations of various experimental approaches, and outline a future prospect of the CME search in high-energy nuclear collisions.