Dominance of Electric Fields in the Charge Splitting of Elliptic Flow

Abstract

In this study, we investigate the impact of electromagnetic fields, highlighting the dominant effect of electric fields on the splitting of elliptic flow, \( v2 \) with transverse momentum (pT). The velocity and temperature profiles of quark-gluon plasma (QGP) is described through thermal model calculations. The electromagnetic field evolution is however determined from the solutions of Maxwell's equations, assuming constant electric and chiral conductivities. We find that the slower decay of the electric fields compared to the magnetic fields makes its impact on the splitting of the elliptic flow more dominant. We further estimated that the maximum value of \( | eF | \), evaluated by averaging the field values over all spatial points on the hypersurface and across all field components, is approximately \( (0.010003 0.000195) \, mπ2 \) for \( sNN = 7.7 \, GeV \), which could describe the splitting of elliptic flow data within the current experimental uncertainty reasonably well.