Origin of Galaxies

Abstract

Milgromian Dynamics (MOND) has been particularly successful in predicting scaling relations for galactic systems, namely the baryonic Tully-Fisher for spirals, the Faber-Jackson for ellipticals and the Radial Acceleration Relation for late-type galaxies. Its essential tenet is the modification of the gravity law at low accelerations. Nevertheless, despite MOND's passed tests, the puzzle of the missing mass on galaxy clusters' scales still persists. One proposed scenario to complete this deficit and apply it further to cosmology is the so-called model. It is composed of a sterile neutrino and the MOND gravity. In this Ph.D. thesis, I have put forward this cosmological idea, conducting hydrodynamical simulations to investigate the structure formation. In the debut attempt, the model was proven capable of reproducing the cosmology, imitating the same expansion history (m ≈ 0.3 and H0 ≈ 67.6 km/s/Mpc), reproducing the CMB phenomenology, while the cosmic web is nicely formed. In the next step, I have optimized the model using Bayesian statistics, re-branding it to opt-. I managed to optimally fit the angular power spectrum of the CMB calculated by Planck, except its fourth peak, but the opt- cosmological parameters changed significantly with respect to its precursor, resulting in a much heavier cosmos, with m ≈ 0.5 and H0 ≈ 55.6 km/s/Mpc. Next, I explore the opt- expansion history, its structure formation and the resulting mass function. The appearance of the early-time structures, firstly in the model, as well as in the opt- model occurs quiet late, at z≈4 and at z≈ 5.5, respectively. Although the resolution has improved from previous studies, the variants cannot explain easily the high-redshift galaxies, observed by JWST.

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