1964 PRL symmetry breaking papers

The 1964 PRL symmetry breaking papers were written by three teams who proposed related but different approaches to explain how mass could arise in local gauge theories. These three papers were written by: Robert Brout and François Englert;[1][2] Peter Higgs;[3] and Gerald Guralnik, C. Richard Hagen, and Tom Kibble (GHK).[4][5] They are credited with the theory of the Higgs mechanism and the prediction of the Higgs field and Higgs boson. Together, these provide a theoretical means by which Goldstone's theorem (a problematic limitation affecting early modern particle physics theories) can be avoided. They showed how gauge bosons can acquire non-zero masses as a result of spontaneous symmetry breaking within gauge invariant models of the universe.[6]

As such, these form the key element of the electroweak theory that forms part of the Standard Model of particle physics, and of many models, such as the Grand Unified Theory, that go beyond it. The papers that introduce this mechanism were published in Physical Review Letters (PRL) and were each recognized as milestone papers by PRL's 50th anniversary celebration.[7] All of the six physicists were awarded the 2010 J. J. Sakurai Prize for Theoretical Particle Physics for this work;[8] Brout, Englert and Higgs received the 2004 Wolf Prize in Physics;[9] and in 2013 Englert and Higgs received the Nobel Prize in Physics.[10]

On 4 July 2012, the two main experiments at the Large Hadron Collider (ATLAS and CMS) at CERN confirmed independently the existence of a previously unknown particle with a mass of about 125 GeV/c2 (about 133 proton masses, on the order of 10−25 kg), which is "consistent with the Higgs boson" and widely believed to be the Higgs boson.[11]

Introduction

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A gauge theory of elementary particles is a very attractive potential framework for constructing the Grand Unified Theory of physics. Such a theory has the very desirable property of being potentially renormalizable—shorthand for saying that all calculational infinities encountered can be consistently absorbed into a few parameters of the theory. However, as soon as one gives mass to the gauge fields, renormalizability is lost, and the theory rendered useless. Spontaneous symmetry breaking is a promising mechanism, which could be used to give mass to the vector gauge particles. A significant difficulty which one encounters, however, is Goldstone's theorem, which states that in any quantum field theory which has a spontaneously broken symmetry there must occur a zero-mass particle. So the problem arises—how can one break a symmetry and at the same time not introduce unwanted zero-mass particles. The resolution of this dilemma lies in the observation that in the case of gauge theories, the Goldstone theorem can be avoided by working in the so-called radiation gauge. This is because the proof of Goldstone's theorem requires manifest Lorentz covariance, a property not possessed by the radiation gauge.

History

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The six authors of the 1964 PRL papers, who received the 2010 J. J. Sakurai Prize for their work. From left to right: Kibble, Guralnik, Hagen, Englert, Brout. Right: Higgs.

Particle physicists study matter made from fundamental particles whose interactions are mediated by exchange particles known as force carriers. At the beginning of the 1960s a number of these particles had been discovered or proposed, along with theories suggesting how they relate to each other, some of which had already been reformulated as field theories in which the objects of study are not particles and forces, but quantum fields and their symmetries.[citation needed] However, attempts to unify known fundamental forces such as the electromagnetic force and the weak nuclear force were known to be incomplete. One known omission was that gauge invariant approaches, including non-abelian models such as Yang–Mills theory (1954), which held great promise for unified theories, also seemed to predict known massive particles as massless.[12] Goldstone's theorem, relating to continuous symmetries within some theories, also appeared to rule out many obvious solutions,[13] since it appeared to show that zero-mass particles would have to also exist that were "simply not seen".[14] According to Gerald Guralnik, physicists had "no understanding" how these problems could be overcome in 1964.[14] In 2014, Guralnik and Carl Hagen wrote a paper that contended that even after 50 years there is still widespread misunderstanding, by physicists and the Nobel Committee, of the Goldstone boson role.[15] This paper, published in Modern Physics Letters A, turned out to be Guralnik's last published work.[16]

Particle physicist and mathematician Peter Woit summarised the state of research at the time:

"Yang and Mills work on non-abelian gauge theory had one huge problem: in perturbation theory it has massless particles which don't correspond to anything we see. One way of getting rid of this problem is now fairly well-understood, the phenomenon of confinement realized in QCD, where the strong interactions get rid of the massless "gluon" states at long distances. By the very early sixties, people had begun to understand another source of massless particles: spontaneous symmetry breaking of a continuous symmetry. What Philip Anderson realized and worked out in the summer of 1962 was that, when you have both gauge symmetry and spontaneous symmetry breaking, the Nambu–Goldstone massless mode can combine with the massless gauge field modes to produce a physical massive vector field. This is what happens in superconductivity, a subject about which Anderson was (and is) one of the leading experts." [text condensed] [12]

The Higgs mechanism is a process by which vector bosons can get rest mass without explicitly breaking gauge invariance, as a byproduct of spontaneous symmetry breaking.[6][17] The mathematical theory behind spontaneous symmetry breaking was initially conceived and published within particle physics by Yoichiro Nambu in 1960,[18] the concept that such a mechanism could offer a possible solution for the "mass problem" was originally suggested in 1962 by Philip Anderson,[19]: 4–5 [20] and Abraham Klein and Benjamin Lee showed in March 1964 that Goldstone's theorem could be avoided this way in at least some non-relativistic cases and speculated it might be possible in truly relativistic cases.[21]

These approaches were quickly developed into a full relativistic model, independently and almost simultaneously, by three groups of physicists: by François Englert and Robert Brout in August 1964;[1] by Peter Higgs in October 1964;[3] and by Gerald Guralnik, Carl Hagen, and Tom Kibble (GHK) in November 1964.[4] Higgs also wrote a response published in September 1964 to an objection by Walter Gilbert,[6][22] which showed that if calculating within the radiation gauge, Goldstone's theorem and Gilbert's objection would become inapplicable.[Note 1] (Higgs later described Gilbert's objection as prompting his own paper.[23]) Properties of the model were further considered by Guralnik in 1965,[24] by Higgs in 1966,[25] by Kibble in 1967,[26] and further by GHK in 1967.[27] The original three 1964 papers showed that when a gauge theory is combined with an additional field that spontaneously breaks the symmetry, the gauge bosons can consistently acquire a finite mass.[6][17][28] In 1967, Steven Weinberg[29] and Abdus Salam[30] independently showed how a Higgs mechanism could be used to break the electroweak symmetry of Sheldon Glashow's unified model for the weak and electromagnetic interactions[31] (itself an extension of work by Julian Schwinger), forming what became the Standard Model of particle physics. Weinberg was the first to observe that this would also provide mass terms for the fermions.[32] [Note 2]

However, the seminal papers on spontaneous breaking of gauge symmetries were at first largely ignored, because it was widely believed that the (non-Abelian gauge) theories in question were a dead-end, and in particular that they could not be renormalised. In 1971–1972, Martinus J, G, Veltman and Gerard 't Hooft proved renormalisation of Yang–Mills was possible in two papers covering massless, and then massive, fields.[32] Their contribution, and others' work on the renormalization group, was eventually "enormously profound and influential",[33] but even with all key elements of the eventual theory published there was still almost no wider interest. For example, Sidney Coleman found in a study that "essentially no-one paid any attention" to Weinberg's paper prior to 1971[34] – now the most cited in particle physics[35] – and even in 1970 according to David Politzer, Glashow's teaching of the weak interaction contained no mention of Weinberg's, Salam's, or Glashow's own work.[33] In practice, Politzer states, almost everyone learned of the theory due to physicist Benjamin Lee, who combined the work of Veltman and 't Hooft with insights by others, and popularised the completed theory.[33] In this way, from 1971, interest and acceptance "exploded" [33] and the ideas were quickly absorbed in the mainstream.[32][33]

The significance of requiring manifest covariance

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Most students who have taken a course in electromagnetism have encountered the Coulomb potential. It basically states that two charged particles attract or repel each other by a force which varies according to the inverse square of their separation. This is fairly unambiguous for particles at rest, but if one or the other is following an arbitrary trajectory the question arises whether one should compute the force using the instantaneous positions of the particles or the so-called retarded positions. The latter recognizes that information cannot propagate instantaneously, rather it propagates at the speed of light. However, the radiation gauge says that one uses the instantaneous positions of the particles, but doesn't violate causality because there are compensating terms in the force equation. In contrast, the Lorenz gauge imposes manifest covariance (and thus causality) at all stages of a calculation. Predictions of observable quantities are identical in the two gauges, but the radiation gauge formulation of quantum field theory avoids Goldstone's theorem.[27]

Summary and impact of the PRL papers

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The three papers written in 1964 were each recognised as milestone papers during Physical Review Letters's 50th anniversary celebration.[28] Their six authors were also awarded the 2010 J. J. Sakurai Prize for Theoretical Particle Physics for this work.[36] (A controversy also arose the same year, because in the event of a Nobel Prize only up to three scientists could be recognised, with six being credited for the papers.[37] ) Two of the three PRL papers (by Higgs and by GHK) contained equations for the hypothetical field that eventually would become known as the Higgs field and its hypothetical quantum, the Higgs boson.[3][4] Higgs's subsequent 1966 paper showed the decay mechanism of the boson; only a massive boson can decay and the decays can prove the mechanism.[citation needed]

Each of these papers is unique and demonstrates different approaches to showing how mass arise in gauge particles. Over the years, the differences between these papers are no longer widely understood, due to the passage of time and acceptance of end-results by the particle physics community. A study of citation indices is interesting—more than 40 years after the 1964 publication in Physical Review Letters there is little noticeable pattern of preference among them, with the vast majority of researchers in the field mentioning all three milestone papers.[citation needed]

In the paper by Higgs the boson is massive, and in a closing sentence Higgs writes that "an essential feature" of the theory "is the prediction of incomplete multiplets of scalar and vector bosons".[3] (Frank Close comments that 1960s gauge theorists were focused on the problem of massless vector bosons, and the implied existence of a massive scalar boson was not seen as important; only Higgs directly addressed it.[38]: 154, 166, 175 ) In the paper by GHK the boson is massless and decoupled from the massive states.[4] In reviews dated 2009 and 2011, Guralnik states that in the GHK model the boson is massless only in a lowest-order approximation, but it is not subject to any constraint and acquires mass at higher orders, and adds that the GHK paper was the only one to show that there are no massless Goldstone bosons in the model and to give a complete analysis of the general Higgs mechanism.[14][5][15] All three reached similar conclusions, despite their very different approaches: Higgs' paper essentially used classical techniques, Englert and Brout's involved calculating vacuum polarization in perturbation theory around an assumed symmetry-breaking vacuum state, and GHK used operator formalism and conservation laws to explore in depth the ways in which Goldstone's theorem explicitly fails.[6]

In addition to explaining how mass is acquired by vector bosons, the Higgs mechanism also predicts the ratio between the W boson and Z boson masses as well as their couplings with each other and with the Standard Model quarks and leptons.[citation needed] Subsequently, many of these predictions have been verified by precise measurements performed at the Large Electron-Positron Collider (LEP) and the Standford Linear Collider (SLC) colliders, thus overwhelmingly confirming that some kind of Higgs mechanism does take place in nature,[39] but the exact manner by which it happens has not yet been discovered.[citation needed] The results of searching for the Higgs boson are expected to provide evidence about how this is realized in nature.[citation needed]

Consequences of the papers

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The resulting electroweak theory and Standard Model have correctly predicted (among other discoveries) weak neutral currents, three bosons, the top and charm quarks, and with great precision, the mass and other properties of some of these.[Note 3] Many of those involved eventually won Nobel Prizes or other renowned awards. A 1974 paper in Reviews of Modern Physics commented that "while no one doubted the [mathematical] correctness of these arguments, no one quite believed that nature was diabolically clever enough to take advantage of them".[40] By 1986 and again in the 1990s it became possible to write that understanding and proving the Higgs sector of the Standard Model was "the central problem today in particle physics." [41][42]

See also

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Notes

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  1. ^ Goldstone's theorem only applies to gauges having manifest Lorentz covariance, a condition that took time to become questioned. But the process of quantisation requires a gauge to be fixed and at this point it becomes possible to choose a gauge such as the 'radiation' gauge which is not invariant over time, so that these problems can be avoided.
  2. ^ A field with the "Mexican hat" potential   and   has a minimum not at zero but at some non-zero value  . By expressing the action in terms of the field   (where   is a constant independent of position), we find the Yukawa term has a component  . Since both   and   are constants, this looks exactly like the mass term for a fermion of mass  . The field   is then the Higgs field.
  3. ^ The success of the Higgs based electroweak theory and Standard Model is illustrated by their predictions of the mass of two particles later detected: the W boson (predicted mass: 80.390±0.018 GeV/c2, experimental measurement: 80.387±0.019 GeV/c2), and the Z boson (predicted mass: 91.1874±0.0021 GeV/c2, experimental measurement: 91.1876±0.0021 GeV/c2). The existence of the Z boson was itself another prediction. Other correct predictions included the weak neutral current, the gluon, and the top and charm quarks, all later proven to exist as the theory said.

References

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  1. ^ a b Englert, F.; Brout, R. (1964). "Broken Symmetry and the Mass of Gauge Vector Mesons". Physical Review Letters. 13 (9): 321–23. Bibcode:1964PhRvL..13..321E. doi:10.1103/PhysRevLett.13.321.
  2. ^ Brout, R.; Englert, F. (1998). "Spontaneous Symmetry Breaking in Gauge Theories: A Historical Survey". arXiv:hep-th/9802142.
  3. ^ a b c d Higgs, P. (1964). "Broken Symmetries and the Masses of Gauge Bosons". Physical Review Letters. 13 (16): 508–509. Bibcode:1964PhRvL..13..508H. doi:10.1103/PhysRevLett.13.508.
  4. ^ a b c d Guralnik, G.; Hagen, C. R.; Kibble, T. W. B. (1964). "Global Conservation Laws and Massless Particles". Physical Review Letters. 13 (20): 585–587. Bibcode:1964PhRvL..13..585G. doi:10.1103/PhysRevLett.13.585.
  5. ^ a b Guralnik, G. S. (2009). "The History of the Guralnik, Hagen and Kibble development of the Theory of Spontaneous Symmetry Breaking and Gauge Particles". International Journal of Modern Physics A. 24 (14): 2601–2627. arXiv:0907.3466. Bibcode:2009IJMPA..24.2601G. doi:10.1142/S0217751X09045431. S2CID 16298371.
  6. ^ a b c d e Kibble, T. W. B. (2009). "Englert-Brout-Higgs-Guralnik-Hagen-Kibble mechanism". Scholarpedia. 4 (1): 6441. Bibcode:2009SchpJ...4.6441K. doi:10.4249/scholarpedia.6441.
  7. ^ Blume, M.; Brown, S.; Millev, Y. (2008). "Letters from the past, a PRL retrospective (1964)". Physical Review Letters. Retrieved 2010-01-30.
  8. ^ "J. J. Sakurai Prize Winners". American Physical Society. 2010. Archived from the original on 12 February 2010. Retrieved 2010-01-30.
  9. ^ Dumé, Isabelle (2004-01-20). "Wolf prize goes to particle theorists". Physics World. Retrieved 2024-04-10.
  10. ^ "The Nobel Prize in Physics 2013".
  11. ^ "CERN experiments observe particle consistent with long-sought Higgs boson" (Press release). CERN. 4 July 2012. Archived from the original on 2016-03-25. Retrieved 2015-06-02.
  12. ^ a b Woit, P. (13 November 2010). "The Anderson–Higgs Mechanism". Not Even Wrong. Columbia University. Retrieved 2012-11-12.
  13. ^ Goldstone, J.; Salam, A.; Weinberg, S. (1962). "Broken Symmetries". Physical Review. 127 (3): 965–970. Bibcode:1962PhRv..127..965G. doi:10.1103/PhysRev.127.965.
  14. ^ a b c Guralnik, G. S. (2011). "The Beginnings of Spontaneous Symmetry Breaking in Particle Physics — Derived From My on the Spot "Intellectual Battlefield Impressions"". arXiv:1110.2253 [physics.hist-ph].
  15. ^ a b Guralnik, G.; Hagen, C. R. (2014). "Where have all the Goldstone bosons gone?". Modern Physics Letters A. 29 (9): 1450046. arXiv:1401.6924. Bibcode:2014MPLA...2950046G. doi:10.1142/S0217732314500461. S2CID 119257339.
  16. ^ Hagen, C. R. (August 2014). "Obituaries - Gerald Stanford Guralnik". Physics Today. 67 (8): 57–58. doi:10.1063/PT.3.2488.
  17. ^ a b Kibble, T. W. B. (2009). "Englert–Brout–Higgs–Guralnik–Hagen–Kibble Mechanism (History)". Scholarpedia. 4 (1): 8741. Bibcode:2009SchpJ...4.8741K. doi:10.4249/scholarpedia.8741.
  18. ^ The Nobel Prize in Physics 2008 – official Nobel Prize website.
  19. ^ Higgs, P. (24 November 2010). "My Life as a Boson" (PDF). King's College London. Archived from the original (PDF) on 2014-05-01. – the original 2001 paper can be found at: Duff, M. J.; Liu, J. T., eds. (2003). 2001 A Spacetime Odyssey: Proceedings of the Inaugural Conference of the Michigan Center for Theoretical Physics. World Scientific Publishing. pp. 86–88. ISBN 978-981-238-231-3.
  20. ^ Anderson, P. (1963). "Plasmons, gauge invariance and mass". Physical Review. 130 (1): 439. Bibcode:1963PhRv..130..439A. doi:10.1103/PhysRev.130.439.
  21. ^ Klein, A.; Lee, B. (1964). "Does Spontaneous Breakdown of Symmetry Imply Zero-Mass Particles?". Physical Review Letters. 12 (10): 266. Bibcode:1964PhRvL..12..266K. doi:10.1103/PhysRevLett.12.266.
  22. ^ Higgs, P. (1964). "Broken symmetries, massless particles and gauge fields". Physics Letters. 12 (2): 132–133. Bibcode:1964PhL....12..132H. doi:10.1016/0031-9163(64)91136-9.
  23. ^ Higgs, P. (24 November 2010). "My Life as a Boson" (PDF). King's College London. Archived from the original (PDF) on 1 May 2014. Retrieved 17 January 2013. Gilbert ... wrote a response to [Klein and Lee's paper] saying 'No, you cannot do that in a relativistic theory. You cannot have a preferred unit time-like vector like that.' This is where I came in, because the next month was when I responded to Gilbert's paper by saying 'Yes, you can have such a thing' but only in a gauge theory with a gauge field coupled to the current.
  24. ^ Guralnik, G. S. (2011). "Gauge Invariance and the Goldstone Theorem". Modern Physics Letters A. 26 (19): 1381–1392. arXiv:1107.4592. Bibcode:2011MPLA...26.1381G. doi:10.1142/S0217732311036188. S2CID 118500709.
  25. ^ Higgs, P. (1966). "Spontaneous Symmetry Breakdown without Massless Bosons". Physical Review. 145 (4): 1156–1163. Bibcode:1966PhRv..145.1156H. doi:10.1103/PhysRev.145.1156.
  26. ^ Kibble 979-0-2600-0043-8 (1967). "Symmetry Breaking in Non-Abelian Gauge Theories". Physical Review. 155 (5): 1554–1561. Bibcode:1967PhRv..155.1554K. doi:10.1103/PhysRev.155.1554.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  27. ^ a b Guralnik, G. S.; Hagen, C. R.; Kibble, T. W. B. (1967). "Broken Symmetries and the Goldstone Theorem" (PDF). In Cool, R. L.; Marsha, R. E. (eds.). Advances in Physics. Vol. 2. Interscience Publishers. pp. 567–708. ISBN 978-0-470-17057-1. Archived from the original (PDF) on 2015-09-24. Retrieved 2014-09-16.
  28. ^ a b "Physical Review Letters – 50th Anniversary Milestone Papers". Physical Review Letters. 2014-02-12. {{cite journal}}: Cite journal requires |journal= (help)
  29. ^ Weinberg, S. (1967). "A Model of Leptons". Physical Review Letters. 19 (21): 1264–1266. Bibcode:1967PhRvL..19.1264W. doi:10.1103/PhysRevLett.19.1264.
  30. ^ Salam, A. (1968). Svartholm, N. (ed.). Elementary Particle Physics: Relativistic Groups and Analyticity. Eighth Nobel Symposium. Stockholm: Almquvist and Wiksell. p. 367.
  31. ^ Glashow, S. L. (1961). "Partial-symmetries of weak interactions". Nuclear Physics. 22 (4): 579–588. Bibcode:1961NucPh..22..579G. doi:10.1016/0029-5582(61)90469-2.
  32. ^ a b c Ellis, J.; Gaillard, M. K.; Nanopoulos, D. V. (2012). "A Historical Profile of the Higgs Boson". arXiv:1201.6045 [hep-ph].
  33. ^ a b c d e f Politzer, D. (2005). "The Dilemma of Attribution". In Tore Frängsmyr (ed.). Les Prix Nobel. The Nobel Prizes 2004. Stockholm: Nobel Foundation. pp. 85–95. Retrieved 22 January 2013. Sidney Coleman published in Science magazine in 1979 a citation search he did documenting that essentially no one paid any attention to Weinberg's Nobel Prize winning paper until the work of 't Hooft (as explicated by Ben Lee). In 1971 interest in Weinberg's paper exploded. I had a parallel personal experience: I took a one-year course on weak interactions from Shelly Glashow in 1970, and he never even mentioned the Weinberg–Salam model or his own contributions.
  34. ^ Coleman, S. (1979). "The 1979 Nobel Prize in Physics". Science. 206 (4424): 1290–1292. Bibcode:1979Sci...206.1290C. doi:10.1126/science.206.4424.1290. PMID 17799637. – discussed by David Politzer in his 2004 Nobel speech.[33]
  35. ^ Letters from the Past – A PRL Retrospective (50 year celebration, 2008)
  36. ^ "J. J. Sakurai Prize for Theoretical Particle Physics". American Physical Society. Retrieved 2016-09-16.
  37. ^ Merali, Z. (4 August 2010). "Physicists get political over Higgs". Nature Magazine. Retrieved 28 December 2011.
  38. ^ Close, F. (2011). The Infinity Puzzle: Quantum Field Theory and the Hunt for an Orderly Universe. Oxford University Press. ISBN 978-0-19-959350-7.
  39. ^ "LEP Electroweak Working Group".
  40. ^ Bernstein, J. (1974). "Spontaneous symmetry breaking, gauge theories, the Higgs mechanism and all that" (PDF). Reviews of Modern Physics. 46 (1): 7–48. Bibcode:1974RvMP...46....7B. doi:10.1103/revmodphys.46.7. Archived from the original (PDF) on 2013-01-21. Retrieved 2012-12-10.
  41. ^ Lucio, J. L.; Zepeda, A., eds. (1987). Proceedings of the II Mexican School of Particles and Fields, Cuernavaca-Morelos, 1986. World Scientific. p. 29. ISBN 978-9971504342.
  42. ^ Gunion, J. F.; Dawson, H. E.; Kane, G.; Haber, S. (1990). The Higgs Hunter's Guide. Perseus Publishing. pp. 11 (?). ISBN 9780786743186.[permanent dead link] – quoted as being in the first (1990) edition of the book by Peter Higgs in his talk "My Life as a Boson", 2001, ref#25.

Further reading

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