Abstract
The symmetric quantum physics of the Universe demonstrates that the massive black holes developing in the post-inflation big-bang prompt the formation of the host galaxies around them. A general correlation between the variety of galaxies and black holes develops, a specific example of which is the celebrated (but not understood) mass correlation between the host elliptical galaxies and their core black holes. The elucidations and predictions in this exposition are inclusive and far-reaching, resolving a myriad of yet unsolved problems and quandaries in the evolving Universe, among which are: how the general galaxy-black hole correlations are established; what is the role of the dark matter and energy in the formation of galaxies and stars; how the spiral galaxies with less predominant black holes are formed; how the early star forming globular cluster emerged with sparse dark matter; why some galaxy mergers give rise to the starbursts, while other mergers switch the star flourishing galaxies off into grave yards; and how could the Universe have wound up as sheets and filaments of galaxy clusters encompassing great voids.
Highlights
The symmetric quantum physics of the Universe demonstrates that the massive black holes developing in the post-inflation big-bang prompt the formation of the host galaxies around them
The elucidations and predictions in this exposition are inclusive and far-reaching, resolving a myriad of yet unsolved problems and quandaries in the evolving Universe, among which are: how the general galaxy-black hole correlations are established; what is the role of the dark matter and energy in the formation of galaxies and stars; how the spiral galaxies with less predominant black holes are formed; how the early star forming globular cluster emerged with sparse dark matter; why some galaxy mergers give rise to the starbursts, while other mergers switch the star flourishing galaxies off into grave yards; and how could the Universe have wound up as sheets and filaments of galaxy clusters encompassing great voids
Based on the symmetric quantum physics [1], this paper explicates the general correlations developing between the variety of host galaxies and the core black holes in the post-inflation big bang
Summary
Based on the symmetric quantum physics [1], this paper explicates the general correlations developing between the variety of host galaxies and the core black holes in the post-inflation big bang. The news of observations of the black holes forming far earlier than expected, and the appearance of the large galaxies at much larger distance than anticipated in the standard theory are mounting with increasingly rapid strides [9] These early galaxies and black holes must have been formed even in seconds of the post-inflation big-bang [10,11]. The so-called dark matter and energy—the non-observables (to humans)— emerged in the major (96%) constituents of the Universe With this phenomenal divulgence, the relevance of the Hermitean-antiHermitean symmetry physics in the quantum theory version of cosmology is firmly established, rendering the standard theory like trying to explain quantum phenomena by classical physics. The standard theory postulates an unseemly two-fold (or more) scalar field interaction, one for the inflation, and the other for flagging it down [23; see p. 77]
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