Primordial Magnetic Fields in Light of Dark Ages Global 21-cm Signal
Vivekanand Mohapatra, Pravin Kumar Natwariya, Alekha C. Nayak
arXiv:2402.18565v1 Announce Type: new
Abstract: We study the constraints on the primordial magnetic fields in light of Dark Ages global 21-cm signal. An early absorption signal in the redshift of $200 leq z leq 30$ is predicted in the $Lambdarm CDM$ model of cosmology. During the Dark Ages, there were no stars, therefore, measuring the global 21-cm signal can provide pristine cosmological information. However, measuring the Dark Ages global 21-cm signal from ground-based telescopes is challenging. To overcome this difficulty, recently lunar and space-based experiments have been proposed, such as FARSIDE, DAPPER, FarView, etc. Primordial magnetic fields can heat the intergalactic medium gas via magnetohydrodynamic effects. We study the effects of magnetic fields on the Dark Ages global 21-cm signal and constrain the present-day strength of primordial magnetic fields and the spectral index. We find that measuring the Dark Ages signal can provide stronger bounds compared to the existing constraints from Planck 2016. Additionally, we also explore the dark-ages consistency ratio which can identify the magnetic heating of IGM by measuring the 21-cm signal at only three different redshifts in future experiments.arXiv:2402.18565v1 Announce Type: new
Abstract: We study the constraints on the primordial magnetic fields in light of Dark Ages global 21-cm signal. An early absorption signal in the redshift of $200 leq z leq 30$ is predicted in the $Lambdarm CDM$ model of cosmology. During the Dark Ages, there were no stars, therefore, measuring the global 21-cm signal can provide pristine cosmological information. However, measuring the Dark Ages global 21-cm signal from ground-based telescopes is challenging. To overcome this difficulty, recently lunar and space-based experiments have been proposed, such as FARSIDE, DAPPER, FarView, etc. Primordial magnetic fields can heat the intergalactic medium gas via magnetohydrodynamic effects. We study the effects of magnetic fields on the Dark Ages global 21-cm signal and constrain the present-day strength of primordial magnetic fields and the spectral index. We find that measuring the Dark Ages signal can provide stronger bounds compared to the existing constraints from Planck 2016. Additionally, we also explore the dark-ages consistency ratio which can identify the magnetic heating of IGM by measuring the 21-cm signal at only three different redshifts in future experiments.