"Seeing Through The Big Bang Into Another Universe" - Gravitational Wave Discovery Confirm An Outrageous 'New' Cosmology
“Your theory is crazy, but it's not crazy enough to be true,” said the great Danish physicist Niels Bohr. Enter Sir Roger Penrose. Correlated noise in the two LIGO gravitational-wave detectors may provide evidence that the universe is governed by Conformal Cyclic Cosmology (CCC) which assumes that the universe consists of a succession of aeons, “the boundaries of infinity,” says Penrose of the University of Oxford. “The Big Bang was not the origin of our universe,” he observed. Penrose proposes that there was an aeon before the Big Bang. The apparent noise is actually a real signal of gravitational waves generated by the decay of hypothetical dark-matter particles.
These particles were predicted by CCC from a previous aeon that can be seen in the cosmic microwave background --electromagnetic radiation left over from an early stage of the universe in Big Bang cosmology. Penose argues that a significant amount of this noise could be a signal of astrophysical or cosmological origin – and specifically CCC. View this brilliant, beautifully produced interview with Penrose...
Physicists at the Niels Bohr Institute, writes Hamish Johnston, editor of physicsworld.com, pointed out that some of the noise in the two LIGO detectors appears to be correlated – with a delay that corresponds to the time it takes for a gravitational wave to travel the more than 3000 kilometers between the instruments. First proposed over a decade ago by Penrose, CCC assumes that each aeon begins with a big bang and proceeds into an unending future in which the universe expands at an accelerating rate. As this expansion becomes infinitely large, Penrose argues that it can be transformed back into the next big bang.
Penrose, Johnston writes, says that a “reasonably robust implication of CCC” is that dark matter consists of particles called erebons – the name deriving from the Greek god of darkness Erebos. As dark matter goes, erebons are extremely heavy and have masses of about 10–5 g. This is roughly the Planck mass and on a par with a grain of sand and about 22 orders of magnitude heavier than a proton. When an erebon decays, Penrose states, it deposits all its energy into a gravitational wave frequencies well above the detection capabilities of LIGO, and would be detected and recorded as near-instantaneous impulses that could be mistaken for noise rather than a signal from the birth of the cosmos.