TITLE:
How Dark Matter Originates from Black Holes
AUTHORS:
Russell Bagdoo
KEYWORDS:
Dark Matter, AGN, Feedback, Lateral Feedback, Change of State, Quantum Phase Transition, Macroscopic Dark Matter Quantum Wave, Q-Balls Solitons, Dibaryons, Superdiffusion
JOURNAL NAME:
Journal of Modern Physics,
Vol.16 No.12,
December
1,
2025
ABSTRACT: In this paper, we discuss the possibility that black holes can indirectly and directly produce dark matter. As well as the possibility that neutron stars and hypothetical quark and boson stars could also produce it. We conjecture that, just as the relativistic jets emitted by radiation from the regions associated with high-mass black holes enable the creation of galaxies, the lateral jets of this same radiation enable the creation of dark matter in the regions surrounding the black hole. We challenge the ΛCDM theory, whose disproportionate cosmological constant leads to the “vacuum catastrophe”. We argue that dark matter appeared after the Big Bang and that the production of the first lumps of the universe would have started with ordinary matter. By way of quantum physics, we explore the nature of dark matter and assume that dark matter and ordinary matter have hydrogen as their deep identity. During a quantum phase transition, molecular hydrogen would become analogous to a Cooper pair whose dibaryons behave like bosons. All matter particles at a certain threshold temperature become phased to form a coherent macroscopic wave of dark matter that has the characteristics of a soliton. When the crust of ordinary matter in hyper-condensed stars—the degeneracy pressure of quantum mechanics—overwhelms gravity, the soliton is repelled into space by “superdiffusion”. Finally, we show that in many cases, a black hole can dissolve in whole or in part into dark matter. We hypothesize that there would be one or more other censorships between the event horizon and cosmic censorship. The trapped surface of one of these pre-Planck censorships would result in a quantum phase transition marking a change of state towards dark matter. This pre-Planck wall would trigger a spatial extension of the black hole into space in the form of a “macroscopic dark matter wave”.