Graviton

This article is about the hypothetical particle. For other uses, see Graviton (disambiguation).
Graviton
Composition Elementary particle
Statistics Bose–Einstein statistics
Interactions Gravitation
Status Theoretical
Symbol G[1]
Antiparticle Self
Theorized 1930s[2]
The name is attributed to Dmitrii Blokhintsev and F. M. Gal'perin in 1934[3]
Mass 0
Mean lifetime Stable
Electric charge 0 e
Spin 2

In theoretical physics, the graviton is a hypothetical elementary particle that mediates the force of gravitation in the framework of quantum field theory.

If it exists, the graviton is expected to be massless (because the gravitational force appears to have unlimited range) and must be a spin-2 boson. A spin-2 particle is also known as a tensor boson, compared to a spin-0 scalar boson and spin-1 vector boson. The spin follows from the fact that the source of gravitation is the stress–energy tensor, a second-order tensor (compared to electromagnetism's spin-1 photon, the source of which is the four-current, a first-order tensor). Additionally, it can be shown that any massless spin-2 field would give rise to a force indistinguishable from gravitation, because a massless spin-2 field would couple to the stress–energy tensor in the same way that gravitational interactions do. As the graviton is hypothetical, its discovery would unite quantum theory with gravity.[4] This result suggests that, if a massless spin-2 particle is discovered, it must be the graviton.[5]

There is no complete theory of gravitons due to an outstanding mathematical problem with renormalization. This problem has been a major motivation for models beyond quantum field theory, such as string theory.

Theory

The three other known forces of nature are mediated by elementary particles: electromagnetism by the photon, the strong interaction by the gluons, and the weak interaction by the W and Z bosons. The hypothesis is that the gravitational interaction is likewise mediated by an – as yet undiscovered – elementary particle, dubbed as the graviton. In the classical limit, the theory would reduce to general relativity and conform to Newton's law of gravitation in the weak-field limit.[6][7][8]

The term graviton was originally coined in 1934 by Soviet physicists Dmitrii Blokhintsev and F. Gal'perin. [9]

Gravitons and renormalisation

When describing graviton interactions, the classical theory of Feynman diagrams, and semiclassical corrections such as one-loop diagrams behave normally. However, Feynman diagrams with at least two loops lead to ultraviolet divergences. These infinite results cannot be removed because quantized general relativity is not perturbatively renormalizable, unlike quantum electrodynamics models such as the Yang–Mills theory. Therefore, incalculable answers are found from the perturbation method by which physicists calculate the probability of a particle to emit or absorb gravitons; and the theory loses predictive veracity. Those problems and the complementary approximation framework are grounds to show that a theory more unified than quantized general relativity is required to describe the behavior near the Planck scale.

Comparison with other forces

Like the force carriers of the other forces (see charged black hole), gravitation plays a role in general relativity, in defining the spacetime in which events take place. In some descriptions, energy modifies the "shape" of spacetime itself, and gravity is a result of this shape, an idea which at first glance may appear hard to match with the idea of a force acting between particles.[10] Because the diffeomorphism invariance of the theory does not allow any particular space-time background to be singled out as the "true" space-time background, general relativity is said to be background independent. In contrast, the Standard Model is not background independent, with Minkowski space enjoying a special status as the fixed background space-time.[11] A theory of quantum gravity is needed in order to reconcile these differences.[12] Whether this theory should be background independent is an open question. The answer to this question will determine our understanding of what specific role gravitation plays in the fate of the universe.[13]

Gravitons in speculative theories

String theory predicts the existence of gravitons and their well-defined interactions. A graviton in perturbative string theory is a closed string in a very particular low-energy vibrational state. The scattering of gravitons in string theory can also be computed from the correlation functions in conformal field theory, as dictated by the AdS/CFT correspondence, or from matrix theory.

A feature of gravitons in string theory is that, as closed strings without endpoints, they would not be bound to branes and could move freely between them. If we live on a brane (as hypothesized by brane theories) this "leakage" of gravitons from the brane into higher-dimensional space could explain why gravitation is such a weak force, and gravitons from other branes adjacent to our own could provide a potential explanation for dark matter. However, if gravitons were to move completely freely between branes this would dilute gravity too much, causing a violation of Newton's inverse square law. To combat this, Lisa Randall found that a three-brane (such as ours) would have a gravitational pull of its own, preventing gravitons from drifting freely, possibly resulting in the diluted gravity we observe while roughly maintaining Newton's inverse square law.[14] See brane cosmology.

A theory by Ahmed Farag Ali and Saurya Das adds quantum mechanical corrections (using Bohm trajectories) to general relativistic geodesics. If gravitons are given a small but non-zero mass, it could explain the cosmological constant without need for dark energy and solve the smallness problem.[15] The theory received an Honorable Mention in the 2014 Essay Competition of the Gravity Research Foundation for explaining the smallness of cosmological constant.[16] Also the theory received an Honorable Mention in the 2015 Essay Competition of the Gravity Research Foundation for naturally explaining the observed large scale homogeneity and isotropy of the universe due to the proposed quantum corrections.[17]

Energy and wavelength

The report on the discovery of gravitational waves[18] specified, in regard to gravitons, that "assuming a modified dispersion relation for gravitational waves, our observations constrain the Compton wavelength of the graviton to be λg > 1013 km, which could be interpreted as a bound on the graviton mass mg < 1.2 × 10−22 eV/c2." This relation between wavelength and energy is calculated with the Planck-Einstein relation, the same formula which relates electromagnetic wavelength to photon energy. However, if gravitons are the quanta of gravitational waves, then the relation between wavelength and corresponding particle energy is fundamentally different for gravitons than for photons, since the Compton wavelength of the graviton is not equal to the gravitational wave wavelength. Instead, the lower-bound graviton Compton wavelength is 5 × 109 times greater than the gravitational wavelength for the GW150914 event, which was ~ 2,000 km. The report did not elaborate on the source of this ratio.

Experimental observation

Unambiguous detection of individual gravitons, though not prohibited by any fundamental law, is impossible with any physically reasonable detector.[19] The reason is the extremely low cross section for the interaction of gravitons with matter. For example, a detector with the mass of Jupiter and 100% efficiency, placed in close orbit around a neutron star, would only be expected to observe one graviton every 10 years, even under the most favorable conditions. It would be impossible to discriminate these events from the background of neutrinos, since the dimensions of the required neutrino shield would ensure collapse into a black hole.[19]

LIGO and Virgo collaborations' observations have directly detected gravitational waves.[18][20][21] Others have postulated that graviton scattering yields gravitational waves as particle interactions yield coherent states.[22] Although these experiments cannot detect individual gravitons, they might provide information about certain properties of the graviton.[23] For example, if gravitational waves were observed to propagate slower than c (the speed of light in a vacuum), that would imply that the graviton has mass (however, gravitational waves must propagate slower than c in a region with non-zero mass density if they are to be detectable).[24] Recent observations of gravitational waves have put an upper bound of 1.2×10−22 eV/c2 on the graviton's mass.[18] Astronomical observations of the kinematics of galaxies, especially the galaxy rotation problem and modified Newtonian dynamics, might point toward gravitons having non-zero mass.[25]

Difficulties and outstanding issues

Most theories containing gravitons suffer from severe problems. Attempts to extend the Standard Model or other quantum field theories by adding gravitons run into serious theoretical difficulties at energies close to or above the Planck scale. This is because of infinities arising due to quantum effects; technically, gravitation is not renormalizable. Since classical general relativity and quantum mechanics seem to be incompatible at such energies, from a theoretical point of view, this situation is not tenable. One possible solution is to replace particles with strings. String theories are quantum theories of gravity in the sense that they reduce to classical general relativity plus field theory at low energies, but are fully quantum mechanical, contain a graviton, and are thought to be mathematically consistent.[26]

See also

References

  1. G is used to avoid confusion with gluons (symbol g)
  2. Rovelli, C. (2001). "Notes for a brief history of quantum gravity". arXiv:gr-qc/0006061Freely accessible [gr-qc].
  3. Blokhintsev, D. I.; Gal'perin, F. M. (1934). "Gipoteza neitrino i zakon sokhraneniya energii" [Neutrino hypothesis and conservation of energy]. Pod Znamenem Marxisma (in Russian). 6: 147–157.
  4. Lightman, A. P.; Press, W. H.; Price, R. H.; Teukolsky, S. A. (1975). "Problem 12.16". Problem book in Relativity and Gravitation. Princeton University Press. ISBN 0-691-08162-X.
  5. For a comparison of the geometric derivation and the (non-geometric) spin-2 field derivation of general relativity, refer to box 18.1 (and also 17.2.5) of Misner, C. W.; Thorne, K. S.; Wheeler, J. A. (1973). Gravitation. W. H. Freeman. ISBN 0-7167-0344-0.
  6. Feynman, R. P.; Morinigo, F. B.; Wagner, W. G.; Hatfield, B. (1995). Feynman Lectures on Gravitation. Addison-Wesley. ISBN 0-201-62734-5.
  7. Zee, A. (2003). Quantum Field Theory in a Nutshell. Princeton University Press. ISBN 0-691-01019-6.
  8. Randall, L. (2005). Warped Passages: Unraveling the Universe's Hidden Dimensions. Ecco Press. ISBN 0-06-053108-8.
  9. Blokhitsev, D.; Gal'perin, F. (1934). "Gipoteza neitrino i zakon sokhraneniya energii (Neutrino Hypothesis and Conservation of Energy)". Pod Znamenem Marxisma (Under the Banner of Marxism). 6: 147–157.
  10. See the other articles on General relativity, Gravitational field, Gravitational wave, etc
  11. Colosi, D.; et al. (2005). "Background independence in a nutshell: The dynamics of a tetrahedron". Classical and Quantum Gravity. 22 (14): 2971. arXiv:gr-qc/0408079Freely accessible. Bibcode:2005CQGra..22.2971C. doi:10.1088/0264-9381/22/14/008.
  12. Witten, E. (1993). "Quantum Background Independence In String Theory". arXiv:hep-th/9306122Freely accessible [hep-th].
  13. Smolin, L. (2005). "The case for background independence". arXiv:hep-th/0507235Freely accessible [hep-th].
  14. Kaku, Michio (2006). Parallel Worlds - The science of alternative universes and our future in the Cosmos. pp. 218–221.
  15. Ali, Ahmed Farag (2014). "Cosmology from quantum potential". Physics Letters B. 741: 276–279. arXiv:1404.3093v3Freely accessible. doi:10.1016/j.physletb.2014.12.057.
  16. Das, Saurya (2014). "Cosmic coincidence or graviton mass?". International Journal of Modern Physics D. 23: 1442017. arXiv:1405.4011Freely accessible. Bibcode:2014IJMPD..2342017D. doi:10.1142/S0218271814420176.
  17. Das, Saurya (2015). "Bose–Einstein condensation as an alternative to inflation". International Journal of Modern Physics D. 24: 1544001. arXiv:1509.02658Freely accessible. Bibcode:2015IJMPD..2444001D. doi:10.1142/S0218271815440010.
  18. 1 2 3 B. P. Abbott et al. (LIGO Scientific Collaboration and Virgo Collaboration) (2016). "Observation of Gravitational Waves from a Binary Black Hole Merger". Physical Review Letters. 116 (6). arXiv:1602.03837Freely accessible. Bibcode:2016PhRvL.116f1102A. doi:10.1103/PhysRevLett.116.061102.
  19. 1 2 Rothman, T.; Boughn, S. (2006). "Can Gravitons be Detected?". Foundations of Physics. 36 (12): 1801–1825. arXiv:gr-qc/0601043Freely accessible. Bibcode:2006FoPh...36.1801R. doi:10.1007/s10701-006-9081-9.
  20. Castelvecchi, Davide; Witze, Witze (February 11, 2016). "Einstein's gravitational waves found at last". Nature News. doi:10.1038/nature.2016.19361. Retrieved 2016-02-11.
  21. "Gravitational waves detected 100 years after Einstein's prediction | NSF - National Science Foundation". www.nsf.gov. Retrieved 2016-02-11.
  22. Senatore, L., Silverstein, E., & Zaldarriaga, M. (2014). New sources of gravitational waves during inflation. Journal of Cosmology and Astroparticle Physics, 2014(08), 016.
  23. Dyson, Freeman (8 October 2013). "Is a graviton detectable?". International Journal of Modern Physics A. 28 (25): 1330041–1–1330035–14. Bibcode:2013IJMPA..2830041D. doi:10.1142/S0217751X1330041X.
  24. Will, C. M. (1998). "Bounding the mass of the graviton using gravitational-wave observations of inspiralling compact binaries". Physical Review D. 57 (4): 2061–2068. arXiv:gr-qc/9709011Freely accessible. Bibcode:1998PhRvD..57.2061W. doi:10.1103/PhysRevD.57.2061.
  25. Trippe, S. (2013), "A Simplified Treatment of Gravitational Interaction on Galactic Scales", J. Kor. Astron. Soc. 46, 41. arXiv:1211.4692
  26. Sokal, A. (July 22, 1996). "Don't Pull the String Yet on Superstring Theory". The New York Times. Retrieved March 26, 2010.
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