|
Fluctuations in de Sitter space Pozicija1 #104159 Cosmologist Sean Carroll has proposed that low entropy may result from fluctuations in De Sitter space - a vacuum except for dark energy and the end point of expanding space time. Some fluctuations lead to cosmological inflation, giving rise to smooth low entropy 'baby universes' - like ours. | This theory is a variation of the inflationary universe theory. However its authors claim that it addresses the key weakness of the latter as an explanation of initial low entropy and the arrow of time: the fact it presupposes an area of low-entropy dark energy. The multiverse theory gives an account of how such areas could arise from fluctuations in empty (de Sitter) space (note Explanation cross link). The theory also implies that the multiverse as a whole will be time-symmetric, with the arrow of time pointing in opposite directions in roughly equal numbers of universes. The excerpt from the paper co-authored with Jennifer Chen (cited below) makes clear the appropriateness of grouping this with the arguments that appeal to anthropic selection. |
+Citavimą (2) - CitavimąPridėti citatąList by: CiterankMapLink[1] The Cosmic Origins of Time's Arrow
Cituoja: Sean M. Carroll - Theoretical physicist, California Institute of Technology Cituojamas: Peter Baldwin 10:34 AM 12 May 2011 GMT Citerank: (4) 104153Why low entropy in the past?How do we account for the low entropy of the early universe reflected in the extreme - but not perfect - homogeneity of the distribution of matter and energy shortly after the Big Bang? When gravity is prominent - as in the early universe - a smooth distribution is unstable and of low entropy.8FFB597, 106948No reason for entropy reversalThere is no good reason to suppose that the entropy gradient will reverse and entropy decrease during the collapsing phase of the cycle. It would be extremely improbable for this to happen for just the reasons Boltzmann outlined in his statistical explanation of the Second Law.13EF597B, 107149Inflationary universeSome cosmologists claim that the inflationary cosmological theory explains the extremely smooth distribution of matter and energy - and hence low entropy - of the early universe. The extremely rapid expansion effectively smooths out any initial irregularities.959C6EF, 107150Presupposes lower entropyAs an explanation for the low initial entropy of the universe, inflationary cosmology does not work since for it to work the dark energy had to begin in an even lower entropy configuration. The puzzle is pushed back a step rather than resolved.13EF597B URL:
| Ištrauka - "Instead let us suppose that the universe started in a high-entropy state, which is its most natural state. A good candidate for such a state is empty space. Like any good high-entropy state, the tendency of empty space is to just sit there unchanging. So the problem is: How do we get our current universe out of a desolate and quiescent spacetime? The secret might lie in the existence of dark energy.
In the presence of dark energy, empty space is not completely empty. Fluctuations of quantum fields give rise to a very low temperature—enormously lower than the temperature of today’s universe but nonetheless not quite absolute zero. All quantum fields experience occasional thermal fluctuations in such a universe. That means it is not perfectly quiescent; if we wait long enough, individual particles and even substantial collections of particles will fluctuate into existence, only to once again disperse into the vacuum. (These are real particles, as opposed to the short-lived “virtual” particles that empty space contains even in the absence of dark energy.)
Among the things that can fluctuate into existence are small patches of ultradense dark energy. If conditions are just right, that patch can undergo inflation and pinch off to form a separate universe all its own—a baby universe. Our universe may be the offspring of some other universe.
Superficially, this scenario bears some resemblance to the standard account of inflation. There, too, we posit that a patch of ultradense dark energy arises by chance, igniting inflation. The difference is the nature of the starting conditions. In the standard account, the patch arose in a wildly fluctuating universe, in which the vast bulk of fluctuations produced nothing resembling inflation. It would seem to be much more likely for the universe to fluctuate straight into a hot big bang, bypassing the inflationary stage altogether. Indeed, as far as entropy is concerned, it would be even more likely for the universe to fluctuate straight into the configuration we see today, bypassing the past 14 billion years of cosmic evolution.
In our new scenario, the preexisting universe was never randomly fluctuating; it was in a very specific state: empty space. What this theory claims—and what remains to be proved—is that the most likely way to create universes like ours from such a preexisting state is to go through a period of inflation, rather than fluctuating there directly. Our universe, in other words, is a fluctuation but not a random one.
This scenario, proposed in 2004 by Jennifer Chen of the University of Chicago and me, provides a provocative solution to the origin of time asymmetry in our observable universe: we see only a tiny patch of the big picture, and this larger arena is fully time-symmetric. Entropy can increase without limit through the creation of new baby universes. Best of all, this story can be told backward and forward in time. Imagine that we start with empty space at some particular moment and watch it evolve into the future and into the past. (It goes both ways because we are not presuming a unidirectional arrow of time.) Baby universes fluctuate into existence in both directions of time, eventually emptying out and giving birth to babies of their own. On ultralarge scales, such a multiverse would look statistically symmetric with respect to time—both the past and the future would feature new universes fluctuating into life and proliferating without bound. Each of them would experience an arrow of time, but half would have an arrow that was reversed with respect to that in the others.
The idea of a universe with a backward arrow of time might seem alarming. If we met someone from such a universe, would they remember the future? Happily, there is no danger of such a rendezvous. In the scenario we are describing, the only places where time seems to run backward are enormously far back in our past—long before our big bang." |
Link[2] Spontaneous Inflation and the Origin of the Arrow of Time
Cituoja: Sean M. Carroll and Jennifer Chen Cituojamas: Peter Baldwin 10:54 AM 12 May 2011 GMT URL: | Ištrauka - ABSTRACT
We suggest that spontaneous eternal inflation can provide a natural explanation for the thermodynamic arrow of time, and discuss the underlying assumptions and consequences of this view. In the absence of inflation, we argue that systems coupled to gravity usually evolve asymptotically to the vacuum, which is the only natural state in a thermodynamic sense. In the presence of a small positive vacuum energy and an appropriate inflaton field, the de Sitter vacuum is unstable to the spontaneous onset of inflation at a higher energy scale. Starting from de Sitter, inflation can increase the total entropy of the universe without bound, creating universes similar to ours in the process. An important consequence of this picture is that inflation occurs asymptotically both forwards and backwards in time, implying a universe that is (statistically) time-symmetric on ultra-large scales.
EXCERPT
There is another, perhaps more persuasive, argument that fluctuations into eternal inflation dominate over those into a conventional Big Bang – namely, that the measure on what is more likely should come from observers in the post-fluctuation universe, rather than from counting events in the pre-fluctuation cold de Sitter space. As has been emphasized often in the eternal-inflation literature, once eternal inflation begins it creates an infinite volume of livable universe in the future. Therefore, even if fluctuations into radiation-dominated universes (or anything similar) are more likely than fluctuations into inflation, most observers will find themselves to be living in a post-inflationary region just because of the infinite volume factor associated with eternal inflation. In practice, using this volume factor to calculate sensible probabilities is extremely difficult at best nevertheless, if our only purpose is to compare inflation to non-inflation, it seems legitimate to appeal to the fecundity of eternal inflation in creating livable regions of spacetime. Although the probability is quite small, fluctuating into inflation is ultimately inevitable, since the total spacetime volume in the cold de Sitter phase is infinite. |
|
|