http://arxiv.org/abs/2210.10183
Primordial magnetic fields (PMFs) are possible candidates for explaining the observed magnetic fields in galaxy clusters. Two competing scenarios of primordial magnetogenesis have been discussed in the literature: inflationary and phase-transitional. We study the amplification of both large- and small-scale correlated magnetic fields corresponding to inflation- and phase-transition-generated PMFs in a massive galaxy cluster. We employ high-resolution magnetohydrodynamic cosmological zoom-in simulations to resolve turbulent motions in the intracluster medium. We find that the turbulent amplification is more efficient for the large-scale, inflationary models while the phase-transition-generated seed fields show moderate growth. The differences between the models are imprinted on the spectral characteristics of the field (such as amplitude and shape of the magnetic power spectrum) and therewith on the final correlation length. We find one order of magnitude difference in the final strengths between the inflation- and phase-transition-generated magnetic field and a factor of $1.5$ difference in their final coherence scales. Thus, the final configuration of the magnetic field retains information on the PMF generation scenarios. Our findings have implications for future extragalactic Faraday rotation surveys with the possibility of distinguishing between different magnetogenesis scenarios.
S. Mtchedlidze, P. Domínguez-Fernández, X. Du, et. al.
Thu, 20 Oct 22
51/74
Comments: 21 pages, 13 figures, comments welcome