Baolian Cheng, Angela V. Olinto, David N. Schramm, James W. Truran
Published 1996-06-26Version 1
In this paper, we revisit in detail the effects of primordial magnetic fields on big bang nucleosynthesis (BBN) including a discussion of the magnetic field geometry and the anomalous magnetic moment. The presence of magnetic fields affects BBN by (1) increasing the weak reaction rates; (2) increasing the electron density due to changes to the electron phase space; and (3) by increasing the expansion rate of the universe, due both to the magnetic field energy density and to the modified electron energy density. Of the effects considered, the increase in the expansion rate due to the magnetic field energy is the most significant for the interests of BBN. The allowed magnetic field intensity at the end of nucleosynthesis (0.01 MeV) is about $2 \times 10^{9}$G and corresponds to an upper limit on the magnetic field energy density of about 28\% of the neutrino energy density ($\rho_B \le 0.28 \rho_\nu$).
Comments: 10 pages
Journal: Phys.Rev.D54:4714-4718,1996
Comment on ``Constraints on the strength of primordial B-fields from big bang nucleosynthesis reexamined''
Big Bang nucleosynthesis, matter-antimatter regions, extra relativistic species, and relic gravitational waves
New Constraints on Radiative Decay of Long-Lived Particles in Big Bang Nucleosynthesis with New $^4$He Photodisintegration Data
