Turning Black Holes into Dark matter

Dark matter, which is over six times more elusive than regular ordinary matter, may be a significant component of the cosmos. We measure the effects of its mass, but the telescopes are unable to catch it. It has the tendency to emit no radiation and to interact only through the action of gravity. This article's main goal is to attempt to define dull matter. Based on our best guess, it is made up of magnetically charged neutrinos and actual attractive monopoles. However, doing so necessitates a significant conceptual leap, as Maxwell's principles must be changed and the electric charge is transformed into an attractive charge. Maxwell's rules would be \"reversed\" in a way that would produce an appealing charge that would replace the electric charge. The unusual form of the Dirac condition, which forced on standard matter that the molecule carries an electric charge and complies with the essential characteristics of the electron, would force within dim matter that the \"dark\" molecule complies with the majority of a neutrino's properties associated with an attractive charge. The article's main goal is to make it seem that dark gaps, especially dynamic supermassive dark gaps, are what determine boring matter. This needs a brief conceptual leap: the dark gap's skyline has a high temperature and a heavy concentration of attractive regions, which leads to a stage move (or broken symmetry) as the matter crosses the skyline. Maxwell's laws may be inverted as a result: the electric charge is replaced with an attractive charge, and the electric current becomes a branch of the attractive current. A third significant conceptual leap is as follows: dull matter would be created outside the dark gap when sterile attractive neutrinos created inside the dark gap crossed dull matter