Superhorizon magnetic fields

Abstract

[Abridged] We analyze the evolution of superhorizon-scale magnetic fields from the end of inflation till today. Whatever is the mechanism responsible for their generation during inflation, we find that a given magnetic mode with wavenumber k evolves, after inflation, according to the values of kηe, nk, and k, where ηe is the conformal time at the end of inflation, nk is the number density spectrum of inflation-produced photons, and k is the phase difference between the two Bogolubov coefficients which characterize the state of that mode at the end of inflation. For any realistic inflationary magnetogenesis scenario, we find that nk-1 |kηe| 1, and three evolutionary scenarios are possible: (i) |k π| = O(1), in which case the evolution of the magnetic spectrum Bk(η) is adiabatic, a2Bk(η) = const, with a being the expansion parameter; (ii) |k π| |kηe|, in which case the evolution is superadiabatic, a2Bk(η) η; (iii) |kηe| |k π| 1 or |kηe| |k π| 1, in which case an early phase of adiabatic evolution is followed, after a time η |k π|/k, by a superadiabatic evolution. Once a given mode reenters the horizon, it remains frozen into the plasma and then evolves adiabatically till today. As a corollary of our results, we find that inflation-generated magnetic fields evolve adiabatically on all scales and for all times in conformal-invariant free Maxwell theory, while they evolve superadiabatically after inflation on superhorizon scales in the non-conformal-invariant Ratra model. The latter result supports our recent claim that the Ratra model can account for the presence of cosmic magnetic fields.