Martin Bojowald had a nice article in SciAm recently ("Follow the Bouncing Universe" in the print edition). Bojowald is a loop quantum gravity theorist: while loop theory has not produced an adequate theory for quantum gravity (and I think it probably won’t), it has produced formalisms that may be useful for constructing models which offer insight into the question of what will replace singularities in QG. This work goes under the rubric “loop quantum cosmology (LQC)”. I also noticed that Bojowald’s senior colleague Abhay Ashtekar has a paper out summarizing the results of work in LQC.
What intrigues me is their exploration of what the region on the other side of the big bounce might be like.
In his article, Bojowald first outlines the idea that space-time in QG is not a continuum, but rather has a fine-scale fundamental structure. These space-time “atoms” follow the rules of quantum mechanics and therefore the physics that prevails at high energies/short distances will differ from general relativity (GR). Specifically, in the loop model, a repulsive force comes into play at high energy densities, preventing singularities. In the case of the big bang, one scenario is that the initial high density state arose when a pre-existing universe collapsed (hence – a “bounce”). Bojowald describes an early, simplified, model which seemed to imply that the pre-existing universe was similar to our own. However, Bojowald says his own subsequent work found that quantum effects would have dominated the immediately pre-existing world:
“So the bounce was not a brief push by a repulsive force, like the collision of billiard balls. Instead, it may have represented the emergence of our universe from an almost unfathomable quantum state – a world in highly fluctuating turmoil.”
Bojowald finishes by discussing how we might learn more about the pre-existing universe from astronomical clues.
Ashtekar’s paper discusses the same research more formally; in addition he also deals with LGC models for black holes, where again singularities are replaced by quantum regions (somewhat surprisingly to me, black holes are somewhat more difficult to model than the big bang itself). He concludes his discussion of the big bang/bounce this way: “Big bang is not the Beginning nor the big crunch the End. Quantum space-time appears to be vastly larger than what general relativity had us believe!”
My takeaway is that a realm of quantum possibilia extends beyond and surrounds us our island of observable cosmos. The old idea of the universe as a relatively straightforward, neatly bounded space-time container must be discarded.
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2 comments:
I think any of the claims of evidence or indications of a Big Bounce, or a universe before the Big Bang, seem highly speculative, and maybe a little silly.
Hawking said that asking what comes before the Big Bang is like asking what's north of the North Pole. Some of these projections based on theories in development sound a little like someone who has just crossed the North Pole and announced "There's another whole Earth on the other side!"
"the emergence of our universe from an almost unfathomable quantum state – a world in highly fluctuating turmoil" sounds like a reasonable summary of the situation close to the Big Bang, but it doesn't make sense to me to describe other regions of the universe which can be reached from that point as existing "before" ours, when time itself is not clearly defined there. I have the same objection to claiming that there is a "cause" of the Big Bang in this description.
Still, fascinating stuff! Enjoying the blog posts.
Thanks very much for your comments.
It is pretty speculative – but we may learn a bit more from looking at cosmic background radiation or someday analyzing gravitational waves. You are right to question the assumptions about time and causality –- loop theory in particular doesn’t deal well with those at all.
There are some other interesting approaches that do have something to say about time and causality that I like, but these theories have a long way to go.
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