Probing correlations of early magnetic fields using mu-distortion

Abstract

The damping of a non-uniform magnetic field between the redshifts of about 104 and 106 injects energy into the photon-baryon plasma and causes the CMB to deviate from a perfect blackbody spectrum, producing a so-called μ-distortion. We can calculate the correlation μ T of this distortion with the temperature anisotropy T of the CMB to search for a correlation B2ζ between the magnetic field B and the curvature perturbation ζ; knowing the B2ζ correlation would help us distinguish between different models of magnetogenesis. Since the perturbations which produce the μ-distortion will be much smaller scale than the relevant density perturbations, the observation of this correlation is sensitive to the squeezed limit of B2ζ, which is naturally parameterized by bNL (a parameter defined analogously to fNL). We find that a PIXIE-like CMB experiments has a signal to noise S/N≈ 1.0 × bNL ( Bμ/10 nG)2, where Bμ is the magnetic field's strength on μ-distortion scales normalized to today's redshift; thus, a 10 nG field would be detectable with bNL=O(1). However, if the field is of inflationary origin, we generically expect it to be accompanied by a curvature bispectrum ζ3 induced by the magnetic field. For sufficiently small magnetic fields, the signal B2 ζ will dominate, but for Bμ 1 nG, one would have to consider the specifics of the inflationary magnetogenesis model. We also discuss the potential post-magnetogenesis sources of a B2ζ correlation and explain why there will be no contribution from the evolution of the magnetic field in response to the curvature perturbation.