FWIW ... if the dark matter state of hydrogen, which is at the deep ground state known as the DDL can be identified as a magnetic monopole then every atom of dark matter would be mutually repulsed by every other, and gravitational attraction would presumably be overwhelmed by magnetic repulsion, thus allowing large clouds of dark matter to form, yet to never condense or aggregate gravitationally. But monopoles have never been detected, correct?
Monatomic hydrogen is normally a strong polarized magnetic particle, and the implication is that in being reduced in volume by a factor of 64,000:1 (or whatever the exact reduction ratio happens to be) something happens to the species to effectively nullify the polarity but not the field, with the result being a "virtual monopole." Or rather, a multipole that looks and acts exactly like a monopole should look and act. The way this could happen in dark matter is via multipolar vortices and a state of multipolar rapid equilibria observed in two-dimensional flows at high Reynolds numbers. The structure has the interesting feature of being completely ''invisible'' in that its presence cannot be detected anywhere outside the support of the vorticity. IOW there may indeed be no monopoles in nature, just rapidly alternating multipoles that look like them. Crowdy almost got it right. http://wwwf.imperial.ac.uk/~dgcrowdy/PubFiles/Paper25.pdf _____________________________________________ Most of the hydrogen in the Universe is in the deeper, denser, colder and more stable state. Ostensibly, it is 64,000 times more compact than hydrogen but is spread out in a "thinner-than-gas" form which does not aggregate. The lack of gravitational self-interaction is the mystery. Does the lower ground state itself "flip" hydrogen into the category of "mirror matter"? i.e. lack of P-symmetry or mirror reflection symmetry?
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