Constraints on Large-Scale Magnetic Fields in the Intergalactic Medium Using Cross-Correlation Methods

Abstract

Large-scale coherent magnetic fields in the intergalactic medium are presumed to play a key role in the formation and evolution of the cosmic web, and in large scale feedback mechanisms. However, they are theorized to be extremely weak, in the nano-Gauss regime. To search for a statistical signature of these weak magnetic fields we perform a cross-correlation between the Faraday rotation measures of 1742 radio galaxies at z > 0.5 and large-scale structure at 0.1 < z< 0.5, as traced by 18 million optical and infrared foreground galaxies. No significant correlation signal was detected within the uncertainty limits. We are able to determine model-dependent 3 σ upper limits on the parallel component of the mean magnetic field strength of filaments in the intergalactic medium of 30 \ nG for coherence scales between 1 and 2.5 \ Mpc, corresponding to a mean upper bound RM enhancement of 3.8 \ rad/m2 due to filaments along all probed sight-lines. These upper bounds are consistent with upper bounds found previously using other techniques. Our method can be used to further constrain intergalactic magnetic fields with upcoming future radio polarization surveys.