Probing Extreme Electromagnetic Fields with the Breit-Wheeler Process

The Relativistic Heavy Ion Collider (RHIC) accelerates nuclei to ultra-relativistic velocities, producing some of the strongest known magnetic fields in the Universe (${10^{14}-10^{15}}$ Tesla). The highly Lorentz-contracted Coulomb fields of the nuclei generate a flux of linearly polarized quasi-real photons that can interact via the Breit-Wheeler process to produce electron-positron pairs (${\gamma\gamma \rightarrow e^+e^-}$). Experimental data presented in this article are consistent with Breit-Wheeler theory across all measured differentials. The detected pairs are produced predominantly at low transverse momentum ($P_{\perp}$) with a smooth invariant mass distribution, with the individual ${e^\pm}$ preferentially aligned along the beam direction, and with a 4th-order modulation in azimuth between the ${e^+e^-}$ pair and ${e^\pm}$ momenta. The $P_{\perp}$ spectrum broadens from large to small impact parameters. Our observation opens new opportunities to study Quantum Chromodynamics under extreme conditions and provides a new tool for interdisciplinary study of extreme electromagnetic fields.