Ekpyrotic universe

The ekpyrotic universe (/ˌɛkpˈrɒtɪk/)[1] is a cosmological model of the early universe that explains the origin of the large-scale structure of the cosmos. The model has also been incorporated in the cyclic universe theory (or ekpyrotic cyclic universe theory), which proposes a complete cosmological history, both the past and future.

Origins

The original ekpyrotic model was introduced by Justin Khoury, Burt Ovrut, Paul Steinhardt and Neil Turok in 2001.[2]

Steinhardt created the name based on the early word ekpyrosis (Ancient Greek: ἐκπύρωσις, ekpyrōsis, "conflagration"); it refers to an ancient Stoic cosmological model in which the universe is caught in an eternal cycle of fiery birth, cooling and rebirth.[3]

The theory addresses the fundamental question that remains unanswered by the Big Bang inflationary model, "What happened before the Big Bang?" The explanation, according to the ekpyrotic theory, is that the Big Bang was actually a big bounce, a transition from a previous epoch of contraction to the present epoch of expansion. The key events that shaped our universe occurred before the bounce, and, in a cyclic version, the universe bounces at regular intervals.[4]

Applications of the theory

The original ekpyrotic models relied on string theory, branes and extra dimensions, but most contemporary ekpyrotic and cyclic models use the same physical ingredients as inflationary models (quantum fields evolving in ordinary space-time). Like Big Bang cosmology, the ekpyrotic theory has accurately described essential features of our universe. It predicts a uniform, flat universe with patterns of hot spots and cold spots, in agreement with observations of the cosmic microwave background (CMB), observations confirmed to higher precision by the WMAP and Planck satellite experiments.[5] Observation of a CMB has long been considered evidence of the Big Bang,[6] but proponents of the ekpyrotic and cyclic theories contend that the CMB is also consistent with a Big Bounce as posited in those models.[7] Other researchers argue that data from the Planck observations of the CMB "significantly limit the viable parameter space of the ekpyrotic/cyclic scenarios."[8] Primordial gravitational waves, if ever observed, may help scientists distinguish between various theories about the origin of the universe.

Implications for cosmology

An advantage of ekpyrotic and cyclic models is that they do not produce a multiverse. This is important because when the effects of quantum fluctuations are properly included in the Big Bang inflationary model, they prevent the universe from achieving the uniformity and flatness that the cosmologists are trying to explain. Instead, inflated quantum fluctuations cause the universe to break up into patches with every conceivable combination of physical properties. Instead of making clear predictions, the Big Bang inflationary theory allows any outcome, so that the properties we observe may be viewed as random chance, resulting from the particular patch of the multiverse in which the Earth resides. Most regions of the multiverse would have very different properties.

Nobel laureate Steven Weinberg has suggested that if the multiverse is true, “the hope of finding a rational explanation for the precise values of quark masses and other constants of the standard model that we observe in our Big Bang is doomed, for their values would be an accident of the particular part of the multiverse in which we live.”[9]

The idea that the properties of our universe are an accident and come from a theory that allows a multiverse of other possibilities is hard to reconcile with the fact that the universe is extraordinarily simple (uniform and flat) on large scales and that elementary particles appear to be described by simple symmetries and interactions. Also, the accidental concept cannot be falsified by an experiment since any future experiments can be viewed as yet other accidental aspects.

In ekpyrotic and cyclic models, smoothing and flattening occurs during a period of slow contraction, so quantum fluctuations are not inflated and cannot produce a multiverse. As a result, the ekpyrotic and cyclic models predict simple physical properties that are consistent with current experimental evidence without producing a multiverse.

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See also

Notes and references

  1. "ekpyrotic". American Heritage Dictionary. Retrieved October 30, 2016.
  2. Khoury, Justin; Ovrut, Burt A.; Steinhardt, Paul J.; Turok, Neil (2001). "The Ekpyrotic Universe: Colliding Branes and the Origin of the Hot Big Bang". Physical Review D. 64 (12): 123522. arXiv:hep-th/0103239. Bibcode:2001PhRvD..64l3522K. doi:10.1103/PhysRevD.64.123522.
  3. 'The dissolution of the universe into fire'. In Stoic philosophy, ekpyrosis, all-engulfing cosmic fire, represents the contractive phase of eternally-recurring destruction and re-creation. On "ekpyrosis" see generally Michael Lapidge, 'Stoic Cosmology,' in John M. Rist, The Stoics, Cambridge University Press, 1978, pp. 161–186, pp. 180–184.
  4. Steinhardt, P. J.; Turok, N. (2002-04-25). "A Cyclic Model of the Universe". Science. 296 (5572): 1436–1439. arXiv:hep-th/0111030. Bibcode:2002Sci...296.1436S. doi:10.1126/science.1070462. PMID 11976408.
  5. Marfatia, Danny; Lee, Hye-Sung; Barger, V. (2003-02-18). "WMAP and Inflation". Physics Letters B. 565: 33–41. arXiv:hep-ph/0302150. Bibcode:2003PhLB..565...33B. doi:10.1016/S0370-2693(03)00757-3.
  6. Veneziano, G. (1998-02-09). "A Simple/Short Introduction to Pre-Big-Bang Physics/Cosmology". arXiv:hep-th/9802057.
  7. Ovrut, Burt A.; Khoury, Justin; Buchbinder, Evgeny I. (2008). "Non-Gaussianities in New Ekpyrotic Cosmology". Physical Review Letters. 100 (17): 171302. arXiv:0710.5172. Bibcode:2008PhRvL.100q1302B. doi:10.1103/PhysRevLett.100.171302. PMID 18518270.
  8. Juvela, M.; Jones, W. C.; Jaffe, T. R.; Jaffe, A. H.; Huffenberger, K. M.; Hovest, W.; Hornstrup, A.; Holmes, W. A.; Hobson, M. (2014). "Planck 2013 Results. XXIV. Constraints on primordial non-Gaussianity". Astronomy & Astrophysics. 571: A24. arXiv:1303.5084. Bibcode:2014A&A...571A..24P. doi:10.1051/0004-6361/201321554.
  9. Weinberg, Steven (November 20, 2007). "Physics: What we do and don't know". The New York Review of Books.

Further reading

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