Hydrogen is still the cosmic default flavor of the day because its atoms so outnumber everything else. A consequential phenomenon as hydrogen orbits a black hole is that obstructs the orbits of the denser particles of other, neutron bearing atoms that travel at speeds above that default velocity.
The profoundly positive charge of central accretion disks brings us to an extreme. As it expands to encroach upon a stellar system, it dispatches negative surface charge in a jiffy and dismantles molecular structure by the same means. The nuclear remains become lofted above the point of capture due to additional lift by galactic traction, but neutron bearing particles to a lesser degree, and those pieces feel the proton drag. Outer protons attain their elevation above the black hole from tangential velocity native to the captured matter augmented by newfound electrostatic repulsion. Imediately below such strata would be protons traveling at a reduced increment of velocity and endowed with endothermic displacement from the outer rim. A proton at that level would have momentarily lost galactic repulsion by neutralizing effect from passing proximity of an electron being snatched from yet higher up as the disk relentlessly expands. Such a step-down represents sacrifice of some tangential velocity in exchange for endothermic displacement (virtual electrical charge) manifested by its reduced altitude. And so it goes along the radius to the galactic rotational axis. But such smearing would be irrevalent jitter, with electrical charge responding with its own exothermic bounce to liberate the proton back to the higher strata. The catch is in the geometry of convergence of electron patterns imploding toward the rotational axis. A dynamic smearing effect on proton locations procedes with increased electrical tension toward the center being offset by increased incidence of electron interference at such positions.
The gradient of energy distribution thus runs from maximum tangential velocity at outer limits with minimal virtual electrical charge there; to maximum virtual electrical charge at the center with minimal velocity as a proton approaches the event horizon. This might tell us that black holes do not get as dizzy as one might expect.
At some time far beyond our future, that distant accretion disk amidst the Milky Way will have gobbled its way out to our sun or whatever remains of it. It will trash it; sending most of our electrons to real outer space, keeping nearly all of the ionic hydrogen, and stuffing everything else into our supermassive black hole, even the internet. The good news is that when the Milky Way goes dark, it will no longer be under acceleration.
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