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Holographic principle

February 06, 2023

"Holographic universe" redirects here. For the Scar Symmetry album, see Holographic Universe (album). For the Epica album, see The Holographic Principle.

The holographic principle is an axiom in string theories and a supposed property of quantum gravity that states that the description of a volume of space can be thought of as encoded on a lower-dimensional boundary to the region — such as a light-like boundary like a gravitational horizon.[1] First proposed by Gerard 't Hooft, it was given a precise string-theory interpretation by Leonard Susskind,[2] who combined his ideas with previous ones of 't Hooft and Charles Thorn.[2][3] Leonard Susskind said, “The three-dimensional world of ordinary experience––the universe filled with galaxies, stars, planets, houses, boulders, and people––is a hologram, an image of reality coded on a distant two-dimensional surface."[4] As pointed out by Raphael Bousso,[5] Thorn observed in 1978 that string theory admits a lower-dimensional description in which gravity emerges from it in what would now be called a holographic way. The prime example of holography is the AdS/CFT correspondence.

The holographic principle was inspired by black hole thermodynamics, which conjectures that the maximum entropy in any region scales with the radius squared, and not cubed as might be expected. In the case of a black hole, the insight was that the information content of all the objects that have fallen into the hole might be entirely contained in surface fluctuations of the event horizon. The holographic principle resolves the black hole information paradox within the framework of string theory.[4] However, there exist classical solutions to the Einstein equations that allow values of the entropy larger than those allowed by an area law (radius squared), hence in principle larger than those of a black hole. These are the so-called "Wheeler's bags of gold". The existence of such solutions conflicts with the holographic interpretation, and their effects in a quantum theory of gravity including the holographic principle are not yet fully understood.[6]

The AdS/CFT correspondence

Main article: AdS/CFT correspondence

The anti-de Sitter/conformal field theory correspondence, sometimes called Maldacena duality (after ref.[7]) or gauge/gravity duality, is a conjectured relationship between two kinds of physical theories. On one side are anti-de Sitter spaces (AdS) which are used in theories of quantum gravity, formulated in terms of string theory or M-theory. On the other side of the correspondence are conformal field theories (CFT) which are quantum field theories, including theories similar to the Yang–Mills theories that describe elementary particles.

The duality represents a major advance in our understanding of string theory and quantum gravity.[8] This is because it provides a non-perturbative formulation of string theory with certain boundary conditions and because it is the most successful realization of the holographic principle.

It also provides a powerful toolkit for studying strongly coupled quantum field theories.[9] Much of the usefulness of the duality results from the fact that it is a strong-weak duality: when the fields of the quantum field theory are strongly interacting, the ones in the gravitational theory are weakly interacting and thus more mathematically tractable. This fact has been used to study many aspects of nuclear and condensed matter physics by translating problems in those subjects into more mathematically tractable problems in string theory.

The AdS/CFT correspondence was first proposed by Juan Maldacena in late 1997.[7] Important aspects of the correspondence were elaborated in articles by Steven Gubser, Igor Klebanov, and Alexander Markovich Polyakov, and by Edward Witten. By 2015, Maldacena's article had over 10,000 citations, becoming the most highly cited article in the field of high energy physics.[10]

Black hole entropy

Main article: Black hole thermodynamics

An object with relatively high entropy is microscopically random, like a hot gas. A known configuration of classical fields has zero entropy: there is nothing random about electric and magnetic fields, or gravitational waves. Since black holes are exact solutions of Einstein's equations, they were thought not to have any entropy either.

But Jacob Bekenstein noted that this leads to a violation of the second law of thermodynamics. If one throws a hot gas with entropy into a black hole, once it crosses the event horizon, the entropy would disappear. The random properties of the gas would no longer be seen once the black hole had absorbed the gas and settled down. One way of salvaging the second law is if black holes are in fact random objects with an entropy that increases by an amount greater than the entropy of the consumed gas.

Bekenstein assumed that black holes are maximum entropy objects—that they have more entropy than anything else in the same volume. In a sphere of radius R, the entropy in a relativistic gas increases as the energy increases. The only known limit is gravitational; when there is too much energy the gas collapses into a black hole. Bekenstein used this to put an upper bound on the entropy in a region of space, and the bound was proportional to the area of the region. He concluded that the black hole entropy is directly proportional to the area of the event horizon.[11] Gravitational time dilation causes time, from the perspective of a remote observer, to stop at the event horizon. Due to the natural limit on maximum speed of motion, this prevents falling objects from crossing the event horizon no matter how close they get to it. Since any change in quantum state requires time to flow, all objects and their quantum information state stay imprinted on the event horizon. Bekenstein concluded that from the perspective of any remote observer, the black hole entropy is directly proportional to the area of the event horizon.

Stephen Hawking had shown earlier that the total horizon area of a collection of black holes always increases with time. The horizon is a boundary defined by light-like geodesics; it is those light rays that are just barely unable to escape. If neighboring geodesics start moving toward each other they eventually collide, at which point their extension is inside the black hole. So the geodesics are always moving apart, and the number of geodesics which generate the boundary, the area of the horizon, always increases. Hawking's result was called the second law of black hole thermodynamics, by analogy with the law of entropy increase, but at first, he did not take the analogy too seriously.

Hawking knew that if the horizon area were an actual entropy, black holes would have to radiate. When heat is added to a thermal system, the change in entropy is the increase in mass-energy divided by temperature:

 

(Here the term δM c2 is substituted for the thermal energy added to the system, generally by non-integrable random processes, in contrast to dS, which is a function of a few "state variables" only, i.e. in conventional thermodynamics only of the Kelvin temperature T and a few additional state variables, such as the pressure.)

If black holes have a finite entropy, they should also have a finite temperature. In particular, they would come to equilibrium with a thermal gas of photons. This means that black holes would not only absorb photons, but they would also have to emit them in the right amount to maintain detailed balance.

Time-independent solutions to field equations do not emit radiation, because a time-independent background conserves energy. Based on this principle, Hawking set out to show that black holes do not radiate. But, to his surprise, a careful analysis convinced him that they do, and in just the right way to come to equilibrium with a gas at a finite temperature. Hawking's calculation fixed the constant of proportionality at 1/4; the entropy of a black hole is one quarter its horizon area in Planck units.[12]

The entropy is proportional to the logarithm of the number of microstates, the enumerated ways a system can be configured microscopically while leaving the macroscopic description unchanged. Black hole entropy is deeply puzzling – it says that the logarithm of the number of states of a black hole is proportional to the area of the horizon, not the volume in the interior.[13]

Later, Raphael Bousso came up with a covariant version of the bound based upon null sheets.[14]

Black hole information paradox

Main article: Black hole information paradox

Hawking's calculation suggested that the radiation which black holes emit is not related in any way to the matter that they absorb. The outgoing light rays start exactly at the edge of the black hole and spend a long time near the horizon, while the infalling matter only reaches the horizon much later. The infalling and outgoing mass/energy interact only when they cross. It is implausible that the outgoing state would be completely determined by some tiny residual scattering.[citation needed]

Hawking interpreted this to mean that when black holes absorb some photons in a pure state described by a wave function, they re-emit new photons in a thermal mixed state described by a density matrix. This would mean that quantum mechanics would have to be modified because, in quantum mechanics, states which are superpositions with probability amplitudes never become states which are probabilistic mixtures of different possibilities.[note 1]

Troubled by this paradox, Gerard 't Hooft analyzed the emission of Hawking radiation in more detail.[15][self-published source?] He noted that when Hawking radiation escapes, there is a way in which incoming particles can modify the outgoing particles. Their gravitational field would deform the horizon of the black hole, and the deformed horizon could produce different outgoing particles than the undeformed horizon. When a particle falls into a black hole, it is boosted relative to an outside observer, and its gravitational field assumes a universal form. 't Hooft showed that this field makes a logarithmic tent-pole shaped bump on the horizon of a black hole, and like a shadow, the bump is an alternative description of the particle's location and mass. For a four-dimensional spherical uncharged black hole, the deformation of the horizon is similar to the type of deformation which describes the emission and absorption of particles on a string-theory world sheet. Since the deformations on the surface are the only imprint of the incoming particle, and since these deformations would have to completely determine the outgoing particles, 't Hooft believed that the correct description of the black hole would be by some form of string theory.

This idea was made more precise by Leonard Susskind, who had also been developing holography, largely independently. Susskind argued that the oscillation of the horizon of a black hole is a complete description[note 2] of both the infalling and outgoing matter, because the world-sheet theory of string theory was just such a holographic description. While short strings have zero entropy, he could identify long highly excited string states with ordinary black holes. This was a deep advance because it revealed that strings have a classical interpretation in terms of black holes.

This work showed that the black hole information paradox is resolved when quantum gravity is described in an unusual string-theoretic way assuming the string-theoretical description is complete, unambiguous and non-redundant.[17] The space-time in quantum gravity would emerge as an effective description of the theory of oscillations of a lower-dimensional black-hole horizon, and suggest that any black hole with appropriate properties, not just strings, would serve as a basis for a description of string theory.

In 1995, Susskind, along with collaborators Tom Banks, Willy Fischler, and Stephen Shenker, presented a formulation of the new M-theory using a holographic description in terms of charged point black holes, the D0 branes of type IIA string theory. The matrix theory they proposed was first suggested as a description of two branes in 11-dimensional supergravity by Bernard de Wit, Jens Hoppe, and Hermann Nicolai. The later authors reinterpreted the same matrix models as a description of the dynamics of point black holes in particular limits. Holography allowed them to conclude that the dynamics of these black holes give a complete non-perturbative formulation of M-theory. In 1997, Juan Maldacena gave the first holographic descriptions of a higher-dimensional object, the 3+1-dimensional type IIB membrane, which resolved a long-standing problem of finding a string description which describes a gauge theory. These developments simultaneously explained how string theory is related to some forms of supersymmetric quantum field theories.

Limit on information density

Information content is defined as the logarithm of the reciprocal of the probability that a system is in a specific microstate, and the information entropy of a system is the expected value of the system's information content. This definition of entropy is equivalent to the standard Gibbs entropy used in classical physics. Applying this definition to a physical system leads to the conclusion that, for a given energy in a given volume, there is an upper limit to the density of information (the Bekenstein bound) about the whereabouts of all the particles which compose matter in that volume. In particular, a given volume has an upper limit of information it can contain, at which it will collapse into a black hole.

This suggests that matter itself cannot be subdivided infinitely many times and there must be an ultimate level of fundamental particles. As the degrees of freedom of a particle are the product of all the degrees of freedom of its sub-particles, were a particle to have infinite subdivisions into lower-level particles, the degrees of freedom of the original particle would be infinite, violating the maximal limit of entropy density. The holographic principle thus implies that the subdivisions must stop at some level.

The most rigorous realization of the holographic principle is the AdS/CFT correspondence by Juan Maldacena. However, J. David Brown and Marc Henneaux had rigorously proved already in 1986, that the asymptotic symmetry of 2+1 dimensional gravity gives rise to a Virasoro algebra, whose corresponding quantum theory is a 2-dimensional conformal field theory.[18]

High-level summary

The physical universe is widely seen to be composed of "matter" and "energy". In his 2003 article published in Scientific American magazine, Jacob Bekenstein speculatively summarized a current trend started by John Archibald Wheeler, which suggests scientists may "regard the physical world as made of information, with energy and matter as incidentals". Bekenstein asks "Could we, as William Blake memorably penned, 'see a world in a grain of sand', or is that idea no more than 'poetic license'?",[19] referring to the holographic principle.

Unexpected connection

Bekenstein's topical overview "A Tale of Two Entropies"[20] describes potentially profound implications of Wheeler's trend, in part by noting a previously unexpected connection between the world of information theory and classical physics. This connection was first described shortly after the seminal 1948 papers of American applied mathematician Claude E. Shannon introduced today's most widely used measure of information content, now known as Shannon entropy. As an objective measure of the quantity of information, Shannon entropy has been enormously useful, as the design of all modern communications and data storage devices, from cellular phones to modems to hard disk drives and DVDs, rely on Shannon entropy.

In thermodynamics (the branch of physics dealing with heat), entropy is popularly described as a measure of the "disorder" in a physical system of matter and energy. In 1877, Austrian physicist Ludwig Boltzmann described it more precisely in terms of the number of distinct microscopic states that the particles composing a macroscopic "chunk" of matter could be in, while still looking like the same macroscopic "chunk". As an example, for the air in a room, its thermodynamic entropy would equal the logarithm of the count of all the ways that the individual gas molecules could be distributed in the room, and all the ways they could be moving.

Energy, matter, and information equivalence

Shannon's efforts to find a way to quantify the information contained in, for example, a telegraph message, led him unexpectedly to a formula with the same form as Boltzmann's. In an article in the August 2003 issue of Scientific American titled "Information in the Holographic Universe", Bekenstein summarizes that "Thermodynamic entropy and Shannon entropy are conceptually equivalent: the number of arrangements that are counted by Boltzmann entropy reflects the amount of Shannon information one would need to implement any particular arrangement" of matter and energy. The only salient difference between the thermodynamic entropy of physics and Shannon's entropy of information is in the units of measure; the former is expressed in units of energy divided by temperature, the latter in essentially dimensionless "bits" of information.

The holographic principle states that the entropy of ordinary mass (not just black holes) is also proportional to surface area and not volume; that volume itself is illusory and the universe is really a hologram which is isomorphic to the information "inscribed" on the surface of its boundary.[13]

Experimental tests

The Fermilab physicist Craig Hogan claims that the holographic principle would imply quantum fluctuations in spatial position[21] that would lead to apparent background noise or "holographic noise" measurable at gravitational wave detectors, in particular GEO 600.[22] However these claims have not been widely accepted, or cited, among quantum gravity researchers and appear to be in direct conflict with string theory calculations.[23]

Analyses in 2011 of measurements of gamma ray burst GRB 041219A in 2004 by the INTEGRAL space observatory launched in 2002 by the European Space Agency shows that Craig Hogan's noise is absent down to a scale of 10−48 meters, as opposed to the scale of 10−35 meters predicted by Hogan, and the scale of 10−16 meters found in measurements of the GEO 600 instrument.[24] Research continues at Fermilab under Hogan as of 2013.[25]

Jacob Bekenstein also claimed to have found a way to test the holographic principle with a tabletop photon experiment.[26]

See also

Notes

  1. ^ except in the case of measurements, which the black hole should not be performing
  2. ^ "Complete description" means all the primary qualities. For example, John Locke (and before him Robert Boyle) determined these to be size, shape, motion, number, and solidity. Such secondary quality information as color, aroma, taste and sound,[16] or internal quantum state is not information that is implied to be preserved in the surface fluctuations of the event horizon. (See however "path integral quantization")

References

Citations
  1. ^ Overbye, Dennis (10 October 2022). "Black Holes May Hide a Mind-Bending Secret About Our Universe - Take gravity, add quantum mechanics, stir. What do you get? Just maybe, a holographic cosmos". The New York Times. Retrieved 10 October 2022.
  2. ^ a b Susskind, Leonard (1995). "The World as a Hologram". Journal of Mathematical Physics. 36 (11): 6377–6396. arXiv:hep-th/9409089. Bibcode:1995JMP....36.6377S. doi:10.1063/1.531249. S2CID 17316840.
  3. ^ Thorn, Charles B. (27–31 May 1991). Reformulating string theory with the 1/N expansion. International A.D. Sakharov Conference on Physics. Moscow. pp. 447–54. arXiv:hep-th/9405069. Bibcode:1994hep.th....5069T. ISBN 978-1-56072-073-7.
  4. ^ a b Susskind, L. (2008). The Black Hole War – My Battle with Stephen Hawking to Make the World Safe for Quantum Mechanics. Little, Brown and Company. p. 410. ISBN 9780316016407.
  5. ^ Bousso, Raphael (2002). "The Holographic Principle". Reviews of Modern Physics. 74 (3): 825–874. arXiv:hep-th/0203101. Bibcode:2002RvMP...74..825B. doi:10.1103/RevModPhys.74.825. S2CID 55096624.
  6. ^ Marolf, Donald (2009). "Black Holes, AdS, and CFTs". General Relativity and Gravitation. 41 (4): 903–17. arXiv:0810.4886. Bibcode:2009GReGr..41..903M. doi:10.1007/s10714-008-0749-7. S2CID 55210840.
  7. ^ a b Maldacena, Juan (March 1998). "The large $N$ limit of superconformal field theories and supergravity". Advances in Theoretical and Mathematical Physics. 2 (2): 231–252. doi:10.4310/ATMP.1998.v2.n2.a1. ISSN 1095-0753.
  8. ^ de Haro et al. 2013, p. 2
  9. ^ Klebanov and Maldacena 2009
  10. ^ "Top Cited Articles of All Time (2014 edition)". INSPIRE-HEP. Retrieved 26 December 2015.
  11. ^ Bekenstein, Jacob D. (January 1981). "Universal upper bound on the entropy-to-energy ratio for bounded systems". Physical Review D. 23 (215): 287–298. Bibcode:1981PhRvD..23..287B. doi:10.1103/PhysRevD.23.287. S2CID 120643289.
  12. ^ Majumdar, Parthasarathi (1998). "Black Hole Entropy and Quantum Gravity". Indian Journal of Physics B. 73 (2): 147. arXiv:gr-qc/9807045. Bibcode:1999InJPB..73..147M.
  13. ^ a b Bekenstein, Jacob D. (August 2003). "Information in the Holographic Universe – Theoretical results about black holes suggest that the universe could be like a gigantic hologram". Scientific American. p. 59.
  14. ^ Bousso, Raphael (1999). "A Covariant Entropy Conjecture". Journal of High Energy Physics. 1999 (7): 004. arXiv:hep-th/9905177. Bibcode:1999JHEP...07..004B. doi:10.1088/1126-6708/1999/07/004. S2CID 9545752.
  15. ^ Anderson, Rupert W. (31 March 2015). The Cosmic Compendium: Black Holes. Lulu.com. ISBN 9781329024588.[self-published source]
  16. ^ Dennett, Daniel (1991). Consciousness Explained. New York: Back Bay Books. p. 371. ISBN 978-0-316-18066-5.
  17. ^ Susskind, L. (February 2003). "The Anthropic landscape of string theory". The Davis Meeting on Cosmic Inflation: 26. arXiv:hep-th/0302219. Bibcode:2003dmci.confE..26S.
  18. ^ Brown, J. D. & Henneaux, M. (1986). "Central charges in the canonical realization of asymptotic symmetries: an example from three-dimensional gravity". Communications in Mathematical Physics. 104 (2): 207–226. Bibcode:1986CMaPh.104..207B. doi:10.1007/BF01211590. S2CID 55421933..
  19. ^ Information in the Holographic Universe
  20. ^ "Information in the Holographic Universe by Jacob D. Bekenstein [July 14,2003]".
  21. ^ Hogan, Craig J. (2008). "Measurement of quantum fluctuations in geometry". Physical Review D. 77 (10): 104031. arXiv:0712.3419. Bibcode:2008PhRvD..77j4031H. doi:10.1103/PhysRevD.77.104031. S2CID 119087922..
  22. ^ Chown, Marcus (15 January 2009). "Our world may be a giant hologram". NewScientist. Retrieved 19 April 2010.
  23. ^ "Consequently, he ends up with inequalities of the type... Except that one may look at the actual equations of Matrix theory and see that none of these commutators is nonzero... The last displayed inequality above obviously can't be a consequence of quantum gravity because it doesn't depend on G at all! However, in the G→0 limit, one must reproduce non-gravitational physics in the flat Euclidean background spacetime. Hogan's rules don't have the right limit so they can't be right." – Luboš Motl, Hogan's holographic noise doesn't exist, 7 Feb 2012
  24. ^ "Integral challenges physics beyond Einstein". European Space Agency. 30 June 2011. Retrieved 3 February 2013.
  25. ^ "Frequently Asked Questions for the Holometer at Fermilab". 6 July 2013. Retrieved 14 February 2014.
  26. ^ Cowen, Ron (22 November 2012). "Single photon could detect quantum-scale black holes". Nature. Retrieved 3 February 2013.
Sources
  • Bousso, Raphael (2002). "The holographic principle". Reviews of Modern Physics. 74 (3): 825–874. arXiv:hep-th/0203101. Bibcode:2002RvMP...74..825B. doi:10.1103/RevModPhys.74.825. S2CID 55096624.
  • 't Hooft, Gerard (1993). "Dimensional Reduction in Quantum Gravity". arXiv:gr-qc/9310026.. 't Hooft's original paper.

External links

  • Alfonso V. Ramallo: Introduction to the AdS/CFT correspondence, arXiv:1310.4319, pedagogical lecture. For the holographic principle: see especially Fig. 1.
  • UC Berkeley's Raphael Bousso gives an introductory lecture on the holographic principle - Video.
  • O'Dowd, Matt (10 April 2019). "The Holographic Universe Explained". PBS Space Time. Archived from the original on 11 December 2021 – via YouTube.

February 06, 2023
holographic, principle, holographic, universe, redirects, here, scar, symmetry, album, holographic, universe, album, epica, album, holographic, principle, holographic, principle, axiom, string, theories, supposed, property, quantum, gravity, that, states, that. Holographic universe redirects here For the Scar Symmetry album see Holographic Universe album For the Epica album see The Holographic Principle The holographic principle is an axiom in string theories and a supposed property of quantum gravity that states that the description of a volume of space can be thought of as encoded on a lower dimensional boundary to the region such as a light like boundary like a gravitational horizon 1 First proposed by Gerard t Hooft it was given a precise string theory interpretation by Leonard Susskind 2 who combined his ideas with previous ones of t Hooft and Charles Thorn 2 3 Leonard Susskind said The three dimensional world of ordinary experience the universe filled with galaxies stars planets houses boulders and people is a hologram an image of reality coded on a distant two dimensional surface 4 As pointed out by Raphael Bousso 5 Thorn observed in 1978 that string theory admits a lower dimensional description in which gravity emerges from it in what would now be called a holographic way The prime example of holography is the AdS CFT correspondence The holographic principle was inspired by black hole thermodynamics which conjectures that the maximum entropy in any region scales with the radius squared and not cubed as might be expected In the case of a black hole the insight was that the information content of all the objects that have fallen into the hole might be entirely contained in surface fluctuations of the event horizon The holographic principle resolves the black hole information paradox within the framework of string theory 4 However there exist classical solutions to the Einstein equations that allow values of the entropy larger than those allowed by an area law radius squared hence in principle larger than those of a black hole These are the so called Wheeler s bags of gold The existence of such solutions conflicts with the holographic interpretation and their effects in a quantum theory of gravity including the holographic principle are not yet fully understood 6 Contents 1 The AdS CFT correspondence 2 Black hole entropy 3 Black hole information paradox 4 Limit on information density 5 High level summary 5 1 Unexpected connection 5 2 Energy matter and information equivalence 6 Experimental tests 7 See also 8 Notes 9 References 10 External linksThe AdS CFT correspondence EditMain article AdS CFT correspondence The anti de Sitter conformal field theory correspondence sometimes called Maldacena duality after ref 7 or gauge gravity duality is a conjectured relationship between two kinds of physical theories On one side are anti de Sitter spaces AdS which are used in theories of quantum gravity formulated in terms of string theory or M theory On the other side of the correspondence are conformal field theories CFT which are quantum field theories including theories similar to the Yang Mills theories that describe elementary particles The duality represents a major advance in our understanding of string theory and quantum gravity 8 This is because it provides a non perturbative formulation of string theory with certain boundary conditions and because it is the most successful realization of the holographic principle It also provides a powerful toolkit for studying strongly coupled quantum field theories 9 Much of the usefulness of the duality results from the fact that it is a strong weak duality when the fields of the quantum field theory are strongly interacting the ones in the gravitational theory are weakly interacting and thus more mathematically tractable This fact has been used to study many aspects of nuclear and condensed matter physics by translating problems in those subjects into more mathematically tractable problems in string theory The AdS CFT correspondence was first proposed by Juan Maldacena in late 1997 7 Important aspects of the correspondence were elaborated in articles by Steven Gubser Igor Klebanov and Alexander Markovich Polyakov and by Edward Witten By 2015 Maldacena s article had over 10 000 citations becoming the most highly cited article in the field of high energy physics 10 Black hole entropy EditMain article Black hole thermodynamics An object with relatively high entropy is microscopically random like a hot gas A known configuration of classical fields has zero entropy there is nothing random about electric and magnetic fields or gravitational waves Since black holes are exact solutions of Einstein s equations they were thought not to have any entropy either But Jacob Bekenstein noted that this leads to a violation of the second law of thermodynamics If one throws a hot gas with entropy into a black hole once it crosses the event horizon the entropy would disappear The random properties of the gas would no longer be seen once the black hole had absorbed the gas and settled down One way of salvaging the second law is if black holes are in fact random objects with an entropy that increases by an amount greater than the entropy of the consumed gas Bekenstein assumed that black holes are maximum entropy objects that they have more entropy than anything else in the same volume In a sphere of radius R the entropy in a relativistic gas increases as the energy increases The only known limit is gravitational when there is too much energy the gas collapses into a black hole Bekenstein used this to put an upper bound on the entropy in a region of space and the bound was proportional to the area of the region He concluded that the black hole entropy is directly proportional to the area of the event horizon 11 Gravitational time dilation causes time from the perspective of a remote observer to stop at the event horizon Due to the natural limit on maximum speed of motion this prevents falling objects from crossing the event horizon no matter how close they get to it Since any change in quantum state requires time to flow all objects and their quantum information state stay imprinted on the event horizon Bekenstein concluded that from the perspective of any remote observer the black hole entropy is directly proportional to the area of the event horizon Stephen Hawking had shown earlier that the total horizon area of a collection of black holes always increases with time The horizon is a boundary defined by light like geodesics it is those light rays that are just barely unable to escape If neighboring geodesics start moving toward each other they eventually collide at which point their extension is inside the black hole So the geodesics are always moving apart and the number of geodesics which generate the boundary the area of the horizon always increases Hawking s result was called the second law of black hole thermodynamics by analogy with the law of entropy increase but at first he did not take the analogy too seriously Hawking knew that if the horizon area were an actual entropy black holes would have to radiate When heat is added to a thermal system the change in entropy is the increase in mass energy divided by temperature d S d M c 2 T displaystyle rm d S frac rm delta M c 2 T dd Here the term dM c2 is substituted for the thermal energy added to the system generally by non integrable random processes in contrast to dS which is a function of a few state variables only i e in conventional thermodynamics only of the Kelvin temperature T and a few additional state variables such as the pressure If black holes have a finite entropy they should also have a finite temperature In particular they would come to equilibrium with a thermal gas of photons This means that black holes would not only absorb photons but they would also have to emit them in the right amount to maintain detailed balance Time independent solutions to field equations do not emit radiation because a time independent background conserves energy Based on this principle Hawking set out to show that black holes do not radiate But to his surprise a careful analysis convinced him that they do and in just the right way to come to equilibrium with a gas at a finite temperature Hawking s calculation fixed the constant of proportionality at 1 4 the entropy of a black hole is one quarter its horizon area in Planck units 12 The entropy is proportional to the logarithm of the number of microstates the enumerated ways a system can be configured microscopically while leaving the macroscopic description unchanged Black hole entropy is deeply puzzling it says that the logarithm of the number of states of a black hole is proportional to the area of the horizon not the volume in the interior 13 Later Raphael Bousso came up with a covariant version of the bound based upon null sheets 14 Black hole information paradox EditMain article Black hole information paradox Hawking s calculation suggested that the radiation which black holes emit is not related in any way to the matter that they absorb The outgoing light rays start exactly at the edge of the black hole and spend a long time near the horizon while the infalling matter only reaches the horizon much later The infalling and outgoing mass energy interact only when they cross It is implausible that the outgoing state would be completely determined by some tiny residual scattering citation needed Hawking interpreted this to mean that when black holes absorb some photons in a pure state described by a wave function they re emit new photons in a thermal mixed state described by a density matrix This would mean that quantum mechanics would have to be modified because in quantum mechanics states which are superpositions with probability amplitudes never become states which are probabilistic mixtures of different possibilities note 1 Troubled by this paradox Gerard t Hooft analyzed the emission of Hawking radiation in more detail 15 self published source He noted that when Hawking radiation escapes there is a way in which incoming particles can modify the outgoing particles Their gravitational field would deform the horizon of the black hole and the deformed horizon could produce different outgoing particles than the undeformed horizon When a particle falls into a black hole it is boosted relative to an outside observer and its gravitational field assumes a universal form t Hooft showed that this field makes a logarithmic tent pole shaped bump on the horizon of a black hole and like a shadow the bump is an alternative description of the particle s location and mass For a four dimensional spherical uncharged black hole the deformation of the horizon is similar to the type of deformation which describes the emission and absorption of particles on a string theory world sheet Since the deformations on the surface are the only imprint of the incoming particle and since these deformations would have to completely determine the outgoing particles t Hooft believed that the correct description of the black hole would be by some form of string theory This idea was made more precise by Leonard Susskind who had also been developing holography largely independently Susskind argued that the oscillation of the horizon of a black hole is a complete description note 2 of both the infalling and outgoing matter because the world sheet theory of string theory was just such a holographic description While short strings have zero entropy he could identify long highly excited string states with ordinary black holes This was a deep advance because it revealed that strings have a classical interpretation in terms of black holes This work showed that the black hole information paradox is resolved when quantum gravity is described in an unusual string theoretic way assuming the string theoretical description is complete unambiguous and non redundant 17 The space time in quantum gravity would emerge as an effective description of the theory of oscillations of a lower dimensional black hole horizon and suggest that any black hole with appropriate properties not just strings would serve as a basis for a description of string theory In 1995 Susskind along with collaborators Tom Banks Willy Fischler and Stephen Shenker presented a formulation of the new M theory using a holographic description in terms of charged point black holes the D0 branes of type IIA string theory The matrix theory they proposed was first suggested as a description of two branes in 11 dimensional supergravity by Bernard de Wit Jens Hoppe and Hermann Nicolai The later authors reinterpreted the same matrix models as a description of the dynamics of point black holes in particular limits Holography allowed them to conclude that the dynamics of these black holes give a complete non perturbative formulation of M theory In 1997 Juan Maldacena gave the first holographic descriptions of a higher dimensional object the 3 1 dimensional type IIB membrane which resolved a long standing problem of finding a string description which describes a gauge theory These developments simultaneously explained how string theory is related to some forms of supersymmetric quantum field theories Limit on information density EditInformation content is defined as the logarithm of the reciprocal of the probability that a system is in a specific microstate and the information entropy of a system is the expected value of the system s information content This definition of entropy is equivalent to the standard Gibbs entropy used in classical physics Applying this definition to a physical system leads to the conclusion that for a given energy in a given volume there is an upper limit to the density of information the Bekenstein bound about the whereabouts of all the particles which compose matter in that volume In particular a given volume has an upper limit of information it can contain at which it will collapse into a black hole This suggests that matter itself cannot be subdivided infinitely many times and there must be an ultimate level of fundamental particles As the degrees of freedom of a particle are the product of all the degrees of freedom of its sub particles were a particle to have infinite subdivisions into lower level particles the degrees of freedom of the original particle would be infinite violating the maximal limit of entropy density The holographic principle thus implies that the subdivisions must stop at some level The most rigorous realization of the holographic principle is the AdS CFT correspondence by Juan Maldacena However J David Brown and Marc Henneaux had rigorously proved already in 1986 that the asymptotic symmetry of 2 1 dimensional gravity gives rise to a Virasoro algebra whose corresponding quantum theory is a 2 dimensional conformal field theory 18 High level summary EditThe physical universe is widely seen to be composed of matter and energy In his 2003 article published in Scientific American magazine Jacob Bekenstein speculatively summarized a current trend started by John Archibald Wheeler which suggests scientists may regard the physical world as made of information with energy and matter as incidentals Bekenstein asks Could we as William Blake memorably penned see a world in a grain of sand or is that idea no more than poetic license 19 referring to the holographic principle Unexpected connection Edit Bekenstein s topical overview A Tale of Two Entropies 20 describes potentially profound implications of Wheeler s trend in part by noting a previously unexpected connection between the world of information theory and classical physics This connection was first described shortly after the seminal 1948 papers of American applied mathematician Claude E Shannon introduced today s most widely used measure of information content now known as Shannon entropy As an objective measure of the quantity of information Shannon entropy has been enormously useful as the design of all modern communications and data storage devices from cellular phones to modems to hard disk drives and DVDs rely on Shannon entropy In thermodynamics the branch of physics dealing with heat entropy is popularly described as a measure of the disorder in a physical system of matter and energy In 1877 Austrian physicist Ludwig Boltzmann described it more precisely in terms of the number of distinct microscopic states that the particles composing a macroscopic chunk of matter could be in while still looking like the same macroscopic chunk As an example for the air in a room its thermodynamic entropy would equal the logarithm of the count of all the ways that the individual gas molecules could be distributed in the room and all the ways they could be moving Energy matter and information equivalence Edit Shannon s efforts to find a way to quantify the information contained in for example a telegraph message led him unexpectedly to a formula with the same form as Boltzmann s In an article in the August 2003 issue of Scientific American titled Information in the Holographic Universe Bekenstein summarizes that Thermodynamic entropy and Shannon entropy are conceptually equivalent the number of arrangements that are counted by Boltzmann entropy reflects the amount of Shannon information one would need to implement any particular arrangement of matter and energy The only salient difference between the thermodynamic entropy of physics and Shannon s entropy of information is in the units of measure the former is expressed in units of energy divided by temperature the latter in essentially dimensionless bits of information The holographic principle states that the entropy of ordinary mass not just black holes is also proportional to surface area and not volume that volume itself is illusory and the universe is really a hologram which is isomorphic to the information inscribed on the surface of its boundary 13 Experimental tests EditThe Fermilab physicist Craig Hogan claims that the holographic principle would imply quantum fluctuations in spatial position 21 that would lead to apparent background noise or holographic noise measurable at gravitational wave detectors in particular GEO 600 22 However these claims have not been widely accepted or cited among quantum gravity researchers and appear to be in direct conflict with string theory calculations 23 Analyses in 2011 of measurements of gamma ray burst GRB 041219A in 2004 by the INTEGRAL space observatory launched in 2002 by the European Space Agency shows that Craig Hogan s noise is absent down to a scale of 10 48 meters as opposed to the scale of 10 35 meters predicted by Hogan and the scale of 10 16 meters found in measurements of the GEO 600 instrument 24 Research continues at Fermilab under Hogan as of 2013 25 Jacob Bekenstein also claimed to have found a way to test the holographic principle with a tabletop photon experiment 26 See also EditBekenstein bound Beyond black holes Bousso s holographic bound Brane cosmology Digital physics Entropic gravity Implicate and explicate order Margolus Levitin theorem Physical cosmology Quantum foamNotes Edit except in the case of measurements which the black hole should not be performing Complete description means all the primary qualities For example John Locke and before him Robert Boyle determined these to be size shape motion number andsolidity Such secondary quality information as color aroma tasteandsound 16 or internal quantum state is not information that is implied to be preserved in the surface fluctuations of the event horizon See however path integral quantization References EditCitations Overbye Dennis 10 October 2022 Black Holes May Hide a Mind Bending Secret About Our Universe Take gravity add quantum mechanics stir What do you get Just maybe a holographic cosmos The New York Times Retrieved 10 October 2022 a b Susskind Leonard 1995 The World as a Hologram Journal of Mathematical Physics 36 11 6377 6396 arXiv hep th 9409089 Bibcode 1995JMP 36 6377S doi 10 1063 1 531249 S2CID 17316840 Thorn Charles B 27 31 May 1991 Reformulating string theory with the 1 N expansion International A D Sakharov Conference on Physics Moscow pp 447 54 arXiv hep th 9405069 Bibcode 1994hep th 5069T ISBN 978 1 56072 073 7 a b Susskind L 2008 The Black Hole War My Battle with Stephen Hawking to Make the World Safe for Quantum Mechanics Little Brown and Company p 410 ISBN 9780316016407 Bousso Raphael 2002 The Holographic Principle Reviews of Modern Physics 74 3 825 874 arXiv hep th 0203101 Bibcode 2002RvMP 74 825B doi 10 1103 RevModPhys 74 825 S2CID 55096624 Marolf Donald 2009 Black Holes AdS and CFTs General Relativity and Gravitation 41 4 903 17 arXiv 0810 4886 Bibcode 2009GReGr 41 903M doi 10 1007 s10714 008 0749 7 S2CID 55210840 a b Maldacena Juan March 1998 The large N limit of superconformal field theories and supergravity Advances in Theoretical and Mathematical Physics 2 2 231 252 doi 10 4310 ATMP 1998 v2 n2 a1 ISSN 1095 0753 de Haro et al 2013 p 2 Klebanov and Maldacena 2009 Top Cited Articles of All Time 2014 edition INSPIRE HEP Retrieved 26 December 2015 Bekenstein Jacob D January 1981 Universal upper bound on the entropy to energy ratio for bounded systems Physical Review D 23 215 287 298 Bibcode 1981PhRvD 23 287B doi 10 1103 PhysRevD 23 287 S2CID 120643289 Majumdar Parthasarathi 1998 Black Hole Entropy and Quantum Gravity Indian Journal of Physics B 73 2 147 arXiv gr qc 9807045 Bibcode 1999InJPB 73 147M a b Bekenstein Jacob D August 2003 Information in the Holographic Universe Theoretical results about black holes suggest that the universe could be like a gigantic hologram Scientific American p 59 Bousso Raphael 1999 A Covariant Entropy Conjecture Journal of High Energy Physics 1999 7 004 arXiv hep th 9905177 Bibcode 1999JHEP 07 004B doi 10 1088 1126 6708 1999 07 004 S2CID 9545752 Anderson Rupert W 31 March 2015 The Cosmic Compendium Black Holes Lulu com ISBN 9781329024588 self published source Dennett Daniel 1991 Consciousness Explained New York Back Bay Books p 371 ISBN 978 0 316 18066 5 Susskind L February 2003 The Anthropic landscape of string theory The Davis Meeting on Cosmic Inflation 26 arXiv hep th 0302219 Bibcode 2003dmci confE 26S Brown J D amp Henneaux M 1986 Central charges in the canonical realization of asymptotic symmetries an example from three dimensional gravity Communications in Mathematical Physics 104 2 207 226 Bibcode 1986CMaPh 104 207B doi 10 1007 BF01211590 S2CID 55421933 Information in the Holographic Universe Information in the Holographic Universe by Jacob D Bekenstein July 14 2003 Hogan Craig J 2008 Measurement of quantum fluctuations in geometry Physical Review D 77 10 104031 arXiv 0712 3419 Bibcode 2008PhRvD 77j4031H doi 10 1103 PhysRevD 77 104031 S2CID 119087922 Chown Marcus 15 January 2009 Our world may be a giant hologram NewScientist Retrieved 19 April 2010 Consequently he ends up with inequalities of the type Except that one may look at the actual equations of Matrix theory and see that none of these commutators is nonzero The last displayed inequality above obviously can t be a consequence of quantum gravity because it doesn t depend on G at all However in the G 0 limit one must reproduce non gravitational physics in the flat Euclidean background spacetime Hogan s rules don t have the right limit so they can t be right Lubos Motl Hogan s holographic noise doesn t exist 7 Feb 2012 Integral challenges physics beyond Einstein European Space Agency 30 June 2011 Retrieved 3 February 2013 Frequently Asked Questions for the Holometer at Fermilab 6 July 2013 Retrieved 14 February 2014 Cowen Ron 22 November 2012 Single photon could detect quantum scale black holes Nature Retrieved 3 February 2013 SourcesBousso Raphael 2002 The holographic principle Reviews of Modern Physics 74 3 825 874 arXiv hep th 0203101 Bibcode 2002RvMP 74 825B doi 10 1103 RevModPhys 74 825 S2CID 55096624 t Hooft Gerard 1993 Dimensional Reduction in Quantum Gravity arXiv gr qc 9310026 t Hooft s original paper External links EditAlfonso V Ramallo Introduction to the AdS CFT correspondence arXiv 1310 4319 pedagogical lecture For the holographic principle see especially Fig 1 UC Berkeley s Raphael Bousso gives an introductory lecture on the holographic principle Video Scientific American article on holographic principle by Jacob Bekenstein O Dowd Matt 10 April 2019 The Holographic Universe Explained PBS Space Time Archived from the original on 11 December 2021 via YouTube Retrieved from https en wikipedia org w index php title Holographic principle amp oldid 1136279958, wikipedia, wiki, book, books, library,

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