Physicists at MIT suggest that early universe, post Big Bang, created microscopic black holes with nuclear charge, possibly explaining dark matter. These primordial black holes formed in a quark-gluon plasma. Researchers propose that primordial black holes may have originated alongside an exotic singularity and could still be detectable. Dark matter is described as massless gravity-generating bubbles from phase transitions during the early universe's formation. A new theory suggests gravity without mass as an explanation for the elusive nature of dark matter.
In the first quintillionth of a second, the universe may have sprouted microscopic black holes with enormous amounts of nuclear charge, @MIT physicists propose. https://t.co/Mj0JJSy0HL
Gravity Without Mass Is A New Explanation For The Failure To Find Dark Matter https://t.co/zAxo0uELVQ
Dark matter: Massless gravity-generating bubbles left over from phase transitions in the formation of the early universe. https://t.co/Twjq2P8nsS
MIT researchers say that primordial black holes may have been born alongside an even more exotic kind of singularity, and they may still be detectable today. https://t.co/iUa3L27uBl
Physicists at MIT propose that the early universe, within the first quintillionth of a second after the Big Bang, produced microscopic black holes with significant nuclear charge. These primordial black holes, formed in a quark-gluon plasma, could explain dark matter's presence… https://t.co/yPEpgfU7Vh
Could we ever see a wormhole in space-time? If they are surrounded by matter like black holes are, they could create roiling fogs of plasma that we could observe. https://t.co/zV4bzcsWB8