Distinguishing the sources of dielectron anisotropic flow at low beam energies

TL;DR

This paper investigates dielectron flow in heavy-ion collisions at low energies, revealing that traditional methods may mask complex dynamics, and proposes a scalar product method to better disentangle source contributions.

Contribution

It introduces a scalar product method to differentiate dielectron sources in flow measurements, improving upon the traditional reaction plane approach.

Findings

Traditional reaction plane method may mask source contributions.

Scalar product method successfully disentangles different dilepton sources.

Calculated dielectron v2 for Ag+Ag collisions at 2.55 GeV.

Abstract

We present calculations of dielectron anisotropic flow in heavy-ion collisions at HADES beam energies from a hadronic transport approach. The ongoing experimental analysis employs the traditional reaction plane method to evaluate the flow coefficients $v_n$ and claims to see isotropic radiation from the thermal quark-gluon plasma. We show in this work, that in the region above the pion mass, the dilepton flow measurement might suffer from cancellation effects that mask the complicated underlying dynamics. Contributions from different baryonic and mesonic resonances show collective behaviour with different signs and lead to an overall vanishing elliptic flow. To differentiate the different contributions, we propose to employ the scalar product method, which exploits the previously measured hadronic flow to create different reference planes. As a proof of concept, we calculate the $v_2$ of dielectrons for Ag+Ag collisions at $\sqrt{s_{NN}}=2.55$ $\mathrm{GeV}$ with both methods and investigate the contribution of each source, concluding that the scalar product method provides the proton and pion tagged flow coefficients as two distinct measurements, disentangling the various dilepton sources.