Revisiting constraints on primordial vector modes and implications for sourced magnetic fields and observed EB power spectrum

Abstract

We revisit regular primordial vector modes sustained by the anisotropic stress of free-streaming neutrinos. We consider two classes of neutrino-sector initial conditions, the neutrino velocity isocurvature mode (νVI) and the neutrino octupole mode (νOCT). We update their observational constraints using current cosmological data, and examine the impact of including the BICEP/Keck 2018 B-mode polarization data. From an MCMC analysis, we obtain the 95\% C.L. upper bounds on the vector-to-scalar ratio as rv<1.55×10-4 and rv<1.04×10-2 for the νVI and νOCT modes at the vector pivot scale k0 = 0.01\, Mpc-1, respectively. We then study two consequences of these bounds. First, we estimate the magnetic fields inevitably generated in the pre-recombination plasma associated with the vector modes. We find that the magnetic-field amplitude at recombination with a coherent length of 1~ Mpc is bounded by B(10-23)\, G and B(10-21)\, G for the νVI and νOCT modes, respetively, which is too small to provide the seed of magnetic fields observed today. Second, assuming the helical vector mode, we compute the induced CMB EB spectrum. We show that even a fully helical primordial vector mode cannot reproduce the currently observed EB signal while remaining consistent with parity-even CMB constraints.