Montonen–Olive duality explained

Montonen–Olive duality or electric–magnetic duality is the oldest known example of strong–weak duality or S-duality according to current terminology. It generalizes the electro-magnetic symmetry of Maxwell's equations by stating that magnetic monopoles, which are usually viewed as emergent quasiparticles that are "composite" (i.e. they are solitons or topological defects), can in fact be viewed as "elementary" quantized particles with electrons playing the reverse role of "composite" topological solitons; the viewpoints are equivalent and the situation dependent on the duality. It was later proven to hold true when dealing with a N = 4 supersymmetric Yang–Mills theory. It is named after Finnish physicist Claus Montonen and British physicist David Olive after they proposed the idea in their academic paper Montonen|Olive|1977}}|Magnetic monopoles as gauge particles? where they state:

S-duality is now a basic ingredient in topological quantum field theories and string theories, especially since the 1990s with the advent of the second superstring revolution. This duality is now one of several in string theory, the AdS/CFT correspondence which gives rise to the holographic principle, being viewed as amongst the most important. These dualities have played an important role in condensed matter physics, from predicting fractional charges of the electron, to the discovery of the magnetic monopole.

Electric–magnetic duality

The idea of a close similarity between electricity and magnetism, going back to the time of André-Marie Ampère and Michael Faraday, was first made more precise with James Clerk Maxwell's formulation of his famous equations for a unified theory of electric and magnetic fields:

The symmetry between

and in these equations is striking. If one ignores the sources, or adds magnetic sources, the equations are invariant under and .

Why should there be such symmetry between

and ? In 1931 Paul Dirac was studying the quantum mechanics of an electric charge moving in a magnetic monopole field, and he found he could only consistently define the wavefunction if the electric charge and magnetic charge satisfy the quantization condition:

Note that from the above if just one monopole of some charge

exists anywhere, then all electric charges must be multiples of the unit . This would "explain" why the magnitude of the electron charge and proton charge should be exactly equal and are the same no matter what electron or proton we are considering, a fact known to hold true to one part in 10²¹. This led Dirac to state:

The magnetic monopole line of research took a step forward in 1974 when Gerard 't Hooft and Alexander Markovich Polyakov independently constructed monopoles not as quantized point particles, but as solitons, in a

Yang–Mills–Higgs system, previously magnetic monopoles had always included a point singularity. The subject was motivated by Nielsen–Olesen vortices.^[1]

At weak coupling, the electrically and magnetically charged objects look very different: one an electron point particle that is weakly coupled and the other a monopole soliton that is strongly coupled. The magnetic fine structure constant is roughly the reciprocal of the usual one:

In 1977 Claus Montonen and David Olive conjectured that at strong coupling the situation would be reversed: the electrically charged objects would be strongly coupled and have non-singular cores, while the magnetically charged objects would become weakly coupled and point like. The strongly coupled theory would be equivalent to weakly coupled theory in which the basic quanta carried magnetic rather than electric charges. In subsequent work this conjecture was refined by Ed Witten and David Olive, they showed that in a supersymmetric extension of the Georgi–Glashow model, the

supersymmetric version (N is the number of conserved supersymmetries), there were no quantum corrections to the classical mass spectrum and the calculation of the exact masses could be obtained. The problem related to the monopole's unit spin remained for this case, but soon after a solution to it was obtained for the case of supersymmetry: Hugh Osborn was able to show that when spontaneous symmetry breaking is imposed in the N = 4 supersymmetric gauge theory, the spins of the topological monopole states are identical to those of the massive gauge particles.

Dual gravity

In 1979–1980, Montonen–Olive duality motivated developing mixed symmetric higher-spin Curtright field.^[2] For the spin-2 case, the gauge-transformation dynamics of Curtright field is dual to graviton in D>4 spacetime. Meanwhile, the spin-0 field, developed by Curtright–Freund,^{[3] [4]} is dual to the Freund-Nambu field,^[5] that is coupled to the trace of its energy–momentum tensor.

The massless linearized dual gravity was theoretically realized in 2000s for wide class of higher-spin gauge fields, especially that is related to

, and supergravity.^{[6] [7] [8] [9]}

A massive spin-2 dual gravity, to lowest order, in D = 4^[10] and N-D^[11] is recently introduced as a theory dual to the massive gravity of Ogievetsky–Polubarinov theory.^[12] The dual field is coupled to the curl of the energy momentum tensor.

Mathematical formalism

In a four-dimensional Yang–Mills theory with N = 4 supersymmetry, which is the case where the Montonen–Olive duality applies, one obtains a physically equivalent theory if one replaces the gauge coupling constant g by 1/g. This also involves an interchange of the electrically charged particles and magnetic monopoles. See also Seiberg duality.

In fact, there exists a larger SL(2,Z) symmetry where both g as well as theta-angle are transformed non-trivially.

The gauge coupling and theta-angle can be combined to form one complex coupling

Since the theta-angle is periodic, there is a symmetry The quantum mechanical theory with gauge group G (but not the classical theory, except in the case when the G is abelian) is also invariant under the symmetry while the gauge group G is simultaneously replaced by its Langlands dual group ^LG and is an integer depending on the choice of gauge group. In the case the theta-angle is 0, this reduces to the simple form of Montonen–Olive duality stated above.

Philosophical implications

The Montonen–Olive duality throws into question the idea that we can obtain a full theory of physics by reducing things into their "fundamental" parts. The philosophy of reductionism states that if we understand the "fundamental" or "elementary" parts of a system we can then deduce all the properties of the system as a whole. Duality says that there is no physically measurable property that can deduce what is fundamental and what is not, the notion of what is elementary and what is composite is merely relative, acting as a kind of gauge symmetry. This seems to favour the view of emergentism, as both the Noether charge (particle) and topological charge (soliton) have the same ontology. Several notable physicists underlined the implications of duality:

However, this argument bears little consequence to the reality of string theory as a whole, and perhaps a better perspective might quest for the implications of the AdS/CFT correspondence, and such deep mathematical connections as Monstrous moonshine. Since experimentally tested evidence bears no resemblance to the String theory landscape; where philosophically an Anthropic principle is at its strongest a self-justification for any unprovable theory.

Further reading

Academic papers

• Castellani . E. . Duality and 'particle' democracy. Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics. 59 . 100–108 . 2016. 1355-2198 . 10.1016/j.shpsb.2016.03.002 . 2017SHPMP..59..100C .
• Dirac . P. A. M. . Paul Dirac . Quantised Singularities in the Electromagnetic Field. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences. 133. 821. 1931. 60–72. 1364-5021 . 10.1098/rspa.1931.0130. 1931RSPSA.133...60D .
• Dirac. P. A. M. . Paul Dirac . The Theory of Magnetic Poles. Physical Review. 74. 7. 1948. 817–830. 0031-899X. 10.1103/PhysRev.74.817 . 1948PhRv...74..817D.
• Duff. M. J.. Michael Duff (physicist) . Khuri. Ramzi R.. Lu. J. X.. String solitons. Physics Reports. 259. 4–5. 1995. 213–326. 0370-1573. 10.1016/0370-1573(95)00002-X. 1995PhR...259..213D. hep-th/9412184. 119524337.
• Font. A.. Ibáñez. L.E.. Lüst. D.. Quevedo. F.. Strong-weak coupling duality and non-perturbative effects in string theory. Physics Letters B. 249. 1. 1990. 35–43. 0370-2693. 10.1016/0370-2693(90)90523-9. 1990PhLB..249...35F. .
• Goddard. P.. Peter Goddard (physicist) . Nuyts. J.. Olive. D. I.. David Olive . Gauge theories and magnetic charge. Nuclear Physics B. 125. 1. 1977. 1–28. 0550-3213. 10.1016/0550-3213(77)90221-8. 1977NuPhB.125....1G. .
• Goddard. P. Peter Goddard (physicist). Olive. D. I.. David Olive. Magnetic monopoles in gauge field theories. Reports on Progress in Physics. 41. 9. 1978. 1357–1437. 0034-4885. 10.1088/0034-4885/41/9/001. 1978RPPh...41.1357G.
• Harvey. J. A.. Jeffrey A. Harvey. Magnetic Monopoles, Duality, and Supersymmetry. High Energy Physics and Cosmology. 12. 66. 1996. hep-th/9603086. 1997hepcbconf...66H.
• Kapustin. A.. Anton Kapustin. Witten. E.. Ed Witten . 2006. Electric-Magnetic Duality And The Geometric Langlands Program. Communications in Number Theory and Physics. 1. 1–236. hep-th/0604151. 2007CNTP....1....1K. 10.4310/CNTP.2007.v1.n1.a1. 30505126.
• Montonen. C.. Claus Montonen. Olive. D. I.. David Olive. Magnetic monopoles as gauge particles?. Physics Letters B. 72. 1. 1977. 117–120. 0370-2693. 10.1016/0370-2693(77)90076-4. 1977PhLB...72..117M.
• Nielsen. H. B.. Holger Bech Nielsen. Olesen. P.. Vortex-line models for dual strings. Nuclear Physics B. 61. 1973. 45–61. 0550-3213. 10.1016/0550-3213(73)90350-7. 1973NuPhB..61...45N. .
• Olive. D. I.. David Olive . The Quantisation of Charges . Lecture at the Symposium "One Hundred Years of H", Pavia 2000. 2001. hep-th/0104063. 2001hep.th....4063O.
• Osborn. H.. Topological charges for N = 4 supersymmetric gauge theories and monopoles of spin 1. Physics Letters B. 83. 3–4. 1979. 321–326. 0370-2693. 10.1016/0370-2693(79)91118-3. 1979PhLB...83..321O .
• Polchinski. J.. Joseph Polchinski. String duality. Reviews of Modern Physics. 68. 4. 1996. 1245–1258. 0034-6861. 10.1103/RevModPhys.68.1245. 1996RvMP...68.1245P. hep-th/9607050. 14147542.
• Polyakov . A. M. . Alexander Markovich Polyakov . 1974 . Particle Spectrum in the Quantum Field Theory . JETP Letters . 0370-274X . 20 . 6 . 194–195 . 1974JETPL..20..194P.
• Rehn. J.. Moessner. R.. Roderich Moessner. Maxwell electromagnetism as an emergent phenomenon in condensed matter. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences . 374. 2075. 2016. 20160093. 1364-503X. 10.1098/rsta.2016.0093. 27458263. 2016RSPTA.37460093R. 1605.05874. 206159482.
• Rickles. D.. Dual theories: 'Same but different' or 'different but same'? . Studies in History and Philosophy of Science Part B: Studies in History and Philosophy of Modern Physics. 59. 62–67. 2015. 1355-2198. 10.1016/j.shpsb.2015.09.005 . 2017SHPMP..59...62R.
• Schwarz. J. H.. John Henry Schwarz. Lectures on superstring and M theory dualities . Nuclear Physics B - Proceedings Supplements. 55. 2. 1997. 1–32. 0920-5632. 10.1016/S0920-5632(97)00070-4. 1997NuPhS..55....1S . hep-th/9607201 . 7541625.
• Seiberg. N.. Nathan Seiberg . Witten. E. . Ed Witten . Electric-magnetic duality, monopole condensation, and confinement in N=2 supersymmetric Yang-Mills theory. Nuclear Physics B. 426. 1. 1994. 19–52. 0550-3213. 10.1016/0550-3213(94)90124-4. 1994NuPhB.426...19S. hep-th/9407087. 14361074. .
• Seiberg. N.. Nathan Seiberg. Electric-magnetic duality in supersymmetric non-Abelian gauge theories. Nuclear Physics B. 435. 1–2. 1995. 129–146. 0550-3213. 10.1016/0550-3213(94)00023-8. 1995NuPhB.435..129S. hep-th/9411149. 18466754.
• Sen. A.. Ashoke Sen. Recent developments in superstring theory. Nuclear Physics B - Proceedings Supplements. 94. 1–3. 2001. 35–48. 0920-5632. 10.1016/S0920-5632(01)00929-X. 2001NuPhS..94...35S. hep-lat/0011073. 17842520.
• Susskind. L.. Leonard Susskind. String Theory. Foundations of Physics. 43. 1. 2011. 174–181. 0015-9018. 10.1007/s10701-011-9620-x. 2013FoPh...43..174S . 189843984.
• 't Hooft . G. . Gerardus 't Hooft . 1974 . Magnetic monopoles in unified gauge theories . Nuclear Physics B . 10.1016/0550-3213(74)90486-6 . 1974NuPhB..79..276T . 79 . 2 . 276–284 . 1874/4686 .
• Witten. E.. Ed Witten . Olive. D. I. . David Olive. Supersymmetry algebras that include topological charges. Physics Letters B. 78. 1. 1978. 97–101. 0370-2693 . 10.1016/0370-2693(78)90357-X. 1978PhLB...78...97W .

Books

• Book: Olive. D.. West . P. C. . Duality and Supersymmetric Theories . 8 July 1999. Cambridge University Press . Cambridge, England . 978-0-521-64158-6 .

Notes and References

1. Nielsen. H.B.. Olesen. P.. September 1973. Vortex-line models for dual strings. Nuclear Physics B. en. 61. 45–61. 10.1016/0550-3213(73)90350-7. 1973NuPhB..61...45N.
2. Curtright. Thomas. December 1985. Generalized gauge fields. Physics Letters B. en. 165. 4–6. 304–308. 10.1016/0370-2693(85)91235-3. 1985PhLB..165..304C.
3. Curtright. Thomas L.. Freund. Peter G.O.. January 1980. Massive dual fields. Nuclear Physics B. en. 172. 413–424. 10.1016/0550-3213(80)90174-1. 1980NuPhB.172..413C.
4. Curtright. Thomas L.. November 2019. Massive dual spinless fields revisited. Nuclear Physics B. en. 948. 114784. 10.1016/j.nuclphysb.2019.114784. 1907.11530. 2019NuPhB.94814784C. free.
5. Freund. Peter G. O.. Nambu. Yoichiro. 1968-10-25. Scalar Fields Coupled to the Trace of the Energy-Momentum Tensor. Physical Review. en. 174. 5. 1741–1743. 10.1103/PhysRev.174.1741. 0031-899X. 1968PhRv..174.1741F.
6. Hull. Christopher M. 2001-09-24. Duality in gravity and higher spin gauge fields. Journal of High Energy Physics. 2001. 9. 027. 10.1088/1126-6708/2001/09/027. 1029-8479. 2001JHEP...09..027H. hep-th/0107149. 9901270.
7. Bekaert. Xavier. Boulanger. Nicolas. Henneaux. Marc. 2003-02-26. Consistent deformations of dual formulations of linearized gravity: A no-go result. Physical Review D. en. 67. 4. 044010. 10.1103/PhysRevD.67.044010. 0556-2821. 2003PhRvD..67d4010B. hep-th/0210278. 14739195.
8. West. Peter. February 2012. Generalised geometry, eleven dimensions and E11. Journal of High Energy Physics. en. 2012. 2. 18. 10.1007/JHEP02(2012)018. 1029-8479. 2012JHEP...02..018W. 1111.1642. 119240022.
9. Godazgar. Hadi. Godazgar. Mahdi. Nicolai. Hermann. February 2014. Generalised geometry from the ground up. Journal of High Energy Physics. en. 2014. 2. 75. 10.1007/JHEP02(2014)075. 1029-8479. 2014JHEP...02..075G. 1307.8295. 53538737.
10. Curtright. T.L.. Alshal. H.. November 2019. Massive dual spin 2 revisited. Nuclear Physics B. en. 948. 114777. 10.1016/j.nuclphysb.2019.114777. 1907.11532. 2019NuPhB.94814777C. free.
11. Alshal. H.. Curtright. T. L.. September 2019. Massive dual gravity in N spacetime dimensions. Journal of High Energy Physics. en. 2019. 9. 63. 10.1007/JHEP09(2019)063. 1029-8479. 2019JHEP...09..063A. 1907.11537. 198953238.
12. Ogievetsky. V.I. Polubarinov. I.V. November 1965. Interacting field of spin 2 and the einstein equations. Annals of Physics. en. 35. 2. 167–208. 10.1016/0003-4916(65)90077-1. 1965AnPhy..35..167O.