====================================================================== = Quantum foam = ====================================================================== Introduction ====================================================================== Quantum foam or spacetime foam is the fluctuation of spacetime on very small scales due to quantum mechanics. The idea was devised by John Wheeler in 1955. Background ====================================================================== With an incomplete theory of quantum gravity, it is impossible to be certain what spacetime would look like at small scales. However, there is no reason that spacetime needs to be fundamentally smooth. It is possible that instead, in a quantum theory of gravity, spacetime would consist of many small, ever-changing regions in which space and time are not definite, but fluctuate in a foam-like manner. Wheeler suggested that the Heisenberg uncertainty principle might imply that over sufficiently small distances and sufficiently brief intervals of time, the "very geometry of spacetime fluctuates". These fluctuations could be large enough to cause significant departures from the smooth spacetime seen at macroscopic scales, giving spacetime a "foamy" character. Experimental results ====================================================================== In 2009 the two MAGIC (Major Atmospheric Gamma-ray Imaging Cherenkov) telescopes detected that among gamma-ray photons arriving from the blazar Markarian 501, some photons at different energy levels arrived at different times, suggesting that some of the photons had moved more slowly and thus contradicting the theory of general relativity's notion of the speed of light being constant, a discrepancy which could be explained by the irregularity of quantum foam. More recent experiments were, however, unable to confirm the supposed variation on the speed of light due to graininess of space. Other experiments involving the polarization of light from distant gamma ray bursts have also produced contradictory results. More Earth-based experiments are ongoing or proposed. Constraints and limits ======================== The large fluctuations characteristic of a spacetime foam would be expected to occur on a length scale on the order of the Planck length. A foamy spacetime would have limits on the accuracy with which distances can be measured because the size of the many quantum bubbles through which light travels will fluctuate. Depending on the spacetime model used, the spacetime uncertainties accumulate at different rates as light travels through the vast distances. X-ray and gamma-ray observations of quasars used data from NASAâs Chandra X-ray Observatory, the Fermi Gamma-ray Space Telescope and ground-based gamma-ray observations from the Very Energetic Radiation Imaging Telescope Array (VERITAS) show that spacetime is uniform down to distances 1000 times smaller than the nucleus of a hydrogen atom. Observations of radiation from nearby quasars by Floyd Stecker of NASA's Goddard Space Flight Center have placed strong experimental limits on the possible violations of Einstein's special theory of relativity implied by the existence of quantum foam. Thus experimental evidence so far has given a range of values in which scientists can test for quantum foam. Random diffusion model ======================== Chandra's X-ray detection of quasars at distances of billions of light years rules out the model where photons diffuse randomly through spacetime foam, similar to a light diffusing by passing through the fog. Holographic model =================== Measurements of quasars at shorter, gamma-ray wavelengths with Fermi, and, shorter wavelengths with VERITAS rule out a second model, called a holographic model with less diffusion. Relation to other theories ====================================================================== The vacuum fluctuations provide vacuum with a non-zero energy known as vacuum energy. Spin foam theory is a modern attempt to make Wheeler's idea quantitative. See also ====================================================================== * Geon * Hawking radiation * Holographic principle * Lorentzian wormhole * Planck time * Quantum fluctuation * Stochastic quantum mechanics * String theory * Sub-Planck * Vacuum energy * Wormhole References ====================================================================== * Minkel, JR (24 November 2003). [http://www.scientificamerican.com/article.cfm?id=borrowed-time-interview-w "Borrowed Time: Interview with Michio Kaku"]. 'Scientific American' * Swarup, A. (2006). [https://www.newscientist.com/article/dn8738-sights-set-on-quantum-froth/ "Sights set on quantum froth"]. 'New Scientist', 189, p. 18, accessed 10 February 2012. License ========= All content on Gopherpedia comes from Wikipedia, and is licensed under CC-BY-SA License URL: http://creativecommons.org/licenses/by-sa/3.0/ Original Article: http://en.wikipedia.org/wiki/Quantum_foam .