Constraining models of Inflationary Magnetogenesis with NANOGrav

Abstract

Generation of magnetic field during inflation can explain its presence over a wide range of scales in the Universe. In Ref.sharma2017, we proposed a model to generate these fields during inflation. These fields have nonzero anisotropic stress which lead to the generation of a stochastic background of gravitational waves (GW) in the early universe. Here we show that for a scenario of magnetogenesis where reheating takes place around QCD epoch, this stochastic GW background lies in the 95\% confidence region of the GW signal probed by NANOGrav collaboration. This is the case when the generated electromagnetic field (EM) energy density is 3-10\% of the background energy density at the end of reheating. For this case, the values of magnetic field strength B0 (3.8-6.9) × 10-11G and its coherence length 30 kpc at the present epoch. These values are for the models in which EM fields are of nonhelical nature. For the helical nature of the fields, these values are B0 (1.1-1.9) × 10-9G and its coherence length 0.8 Mpc.