According to a paper posted to the arXiv pre-print server last week, the difference between an everyday supermassive black hole and a space-time tunneling wormhole may be a lacing of dark matter. While it sounds like crank fodder of the sort that not infrequently winds up on arXiv, the idea may hold actual water.
The theory pertains to one particular proposed form of dark matter known as axionic dark matter. Axions, a hypothesized fundamental particle of matter relating to the strong nuclear force, aren't the only proposed candidate for dark matter, but as searches for WIMPs (weakly-interacting massive particles)—far and away the favored proposed particle comprising dark matter—come up empty, axionic dark matter has become a more and more plausible scenario. As theorized, dark matter axions would permeate the universe as an energetic condensate, interacting only very weakly via the electromagnetic force and existing as a kind of ghostly cosmic foam.
Crucially, while individual axions would be very light, they would together make up enough mass to account for the dark matter halos that form the gravitational scaffolding of galaxies. Axions are currently being hunted for via experiments involving giant Earth-based mirrors.
The wormhole idea has to do with how axions interact with electromagnetic fields. "Many authors have considered the electromagnetic interaction of axion particles," writes Konstantinos Dimopoulos of Lancaster University in the UK. "However, the effect of this interaction to the axionic condensate itself has been largely ignored, assuming that it is negligible." Maybe there's more to it, Dimopoulos surmises.
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