1. Black Holes

            According to the above hyperspace model, a Black Hole (BH) would be a relatively large window to hyperspace, e.g. the mass (particle density) of the corresponding body would be so great, that it could no longer be supported by the fabric of spacetime, thus “falling” into hyperspace. The strong gravitational attraction of BHs can be now easily understood as a strong hyperspace suction effect on particles in our 3-D world. The infinitely dense and infinitely small body that is attributed usually to BHs, can be understood as a particle that has exceeded certain limit and that has been absorbed by hyperspace. This limit would be analogous to the Chandrasekhar limit, e.g. the mass limit, beyond which an exploding star becomes a BH. The concepts “infinitely dense and infinitely small” are concepts relative to our 3-D universe. In hyperspace, a BH is probably nothing else than a conventional body with a certain density and size, since the ability of  hyperspace to support massive bodies is probably much higher than that of 3-D space because of the 2 additional degrees of freedom (dimensions).

The hyperspace model is a generalization and would work with any field proposed in literature (Higgs-field, BF, ZPF, etc.). It has an intrinsic beauty since it explains even extraordinarily strange relativistic phenomena like BHs in plane and almost Newtonian words. Everybody understands the meaning of suction, as a force produced by the tendency of matter to dissipate in hyperspace whenever possible, since any increase of the size of a space will produce a force that forces matter literally to fill up this new empty space.

Small BHs could be produced artificially by using a conventional hydrogen bomb and fusion material at 0ºK instead of higher temperatures. At 0ºK, there would be no radiation leaving the atoms when the bomb compressed the material, thus allowing a much more efficient compression than at higher temperatures. If we compressed in this way hydrogen at 0ºK, apart from different fusion materials, we would also get some hyperdense material in form of small BHs or neutron matter. Hydrogen is the ideal candidate for such compression since at 0ºK, it would build an absolutely dense proton body once we had demagnetized and deelectrified atoms (e.g. elimination of any orbiting or free electron).

            Once we had produced and stabilized such matter by placing it i.e. in the outer space, we could use it to access the hyperspace. The more matter we managed to compress, the more the resulting BH would “fall” into hyperspace. We could also condense heavy atoms like gold atoms at 0ºK reaching an even much more dense body (this would require higher compression energy and a more efficient cooling of the device).