Cycles of Time by Roger Penrose
This isn’t really a review of “Cycles of Time”: I’m not going to discuss the structure of the book or the quality of the writing. Instead I’ve tried for my own benefit to summarise what I learned from reading it. I hope I’ve done Professor Penrose justice. Any rubbish I’ve written is my responsibility, not his!
A big problem with our current best description of the evolution of the universe is the Big Bang. There are good theories and explanations about why the universe looks like it does 14 billion years on, but what Banged and why is rather vague. An explanation based on a random quantum event is about the best going but it does seem rather unsatisfactory. An associated problem comes from the second law of thermodynamics, which requires entropy (‘randomness’) to be always increasing, which implies it had a very low value at the moment of the Big Bang.
Roger Penrose’s latest book addresses the question “What came before the Big Bang?” For those who don’t know why Penrose’s thoughts are worth considering, I quote from Wikipedia:
Sir Roger Penrose OM FRS (born 8 August 1931) is an English mathematical physicist and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute, University of Oxford and Emeritus Fellow of Wadham College. He has received a number of prizes and awards, including the 1988 Wolf Prize for physics which he shared with Stephen Hawking for their contribution to our understanding of the universe. He is renowned for his work in mathematical physics, in particular his contributions to general relativity and cosmology. He is also a recreational mathematician and philosopher.
Although he says he has relegated the difficult maths to appendices I admit I can’t even follow the mathematics (geometry) in the main text. Conformal scaling of tensors in field equations, if that makes sense, is more than I can cope with. But I think I get the general idea. The universe, or spacetime, has a geometry. Not the plane Euclidean geometry some of us learned at school but something much more complex. Penrose’s analysis is based on conformal geometry where shapes and angles are preserved when the underlying ‘fabric’ is distorted. In this geometry, infinity becomes a definite boundary rather than an unattainable end point always approached but never reached.
The universe as we know it is generally accepted to be about 13.7 billion years old. That’s 1.37×1010 years. Continue for all that time ten times over. It’s now 1.37×1011 years old. Do all those 1011 years ten times over and it’s 1012 years. Penrose proposes that over an unthinkable timescale of the order of 10100 years, which he calls an aeon, the universe comes to a final end which is the start of another.
He calls his theory Conformal Cyclical Cosmology. The length of an aeon is determined by the expansion and cooling of the universe, where long after the stars have died and become cold dwarfs or black holes spacetime consists of these cold massive objects and low-energy photons and gravitons. The black holes themselves lose mass by Hawking radiation, which takes place over these vast periods of time. Estimating the length of an aeon at 10100 years is based on the time it would take for the universe to cool to a temperature at which the largest black holes would radiate their mass away and die with a final ‘pop’.
General relativity implies that massless particles (photons, gravitons) are oblivious to time. And if you can’t measure time you can’t measure distance (trust me on this). So the condition of the universe near the end of an aeon is such that time and distance no longer exist but conformal geometry will still apply. Penrose shows that in these circumstances there can be a smooth and continuous transition from ‘before’ a Big Bang to ‘after’. He even suggests a mechanism which could transfer observable effects from one aeon to the next which could be detectable in the cosmic background microwave radiation.
Penrose addresses the entropy problem I mentioned earlier and gives a fairly detailed analysis of how the far-future phase of the universe can lose entropy as matter is drawn into black holes. But there is one vital part of his analysis (if I understand anything at all about it) which is still purely speculative. His theory requires that over the length of an aeon all the mass of the universe disappears and is converted to massless radiation. There is no evidence to support this idea at the moment, but Penrose suggests that our observational timescale is so short relative to the 10100 or so years of an aeon that the universe might just not have been around long enough for such a process to become evident.
Although Penrose explains mathematically how certain aspects of a dying aeon could make a smooth transition through a new Big Bang into the start of a new aeon I failed to find an account of what this might involve in physical terms. How does a cold, dark, radiation-filled universe transform into a violent exploding maelstrom of energy? It’s very hard to imagine. In my naive ignorance I feel it would be nice to find an answer in the maths of String Theory and Quantum Field Theory (see for example “The Elegant Universe” by Brian Greene) – which Penrose does not support. Here the universe has several more ‘hidden’ dimensions, and dimensions can have a strange symmetrical property such that whether a dimension’s radius of curvature is defined as R or 1/R its properties are the same. So perhaps at the ‘end of time’ when the radii of curvature of spacetime have become infinitely large the geometry transforms into infinitely small radii and the next Big Bang takes it from there. But this is just my whimsical fancy – don’t pay it any attention. Unless of course it turns out to be right, in which case please send the Nobel Prize invitation c/o this website.