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Top quark condensate

December 18, 2023

In particle physics, the top quark condensate theory (or top condensation) is an alternative to the Standard Model fundamental Higgs field, where the Higgs boson is a composite field, composed of the top quark and its antiquark. The top quark-antiquark pairs are bound together by a new force called topcolor, analogous to the binding of Cooper pairs in a BCS superconductor, or mesons in the strong interactions. The top quark is very heavy, with a measured mass of approximately 174 GeV (comparable to the electroweak scale), and so its Yukawa coupling is of order unity, suggesting the possibility of strong coupling dynamics at high energy scales. This model attempts to explain how the electroweak scale may match the top quark mass.

History edit

The idea was described by Yoichiro Nambu[citation needed] and subsequently developed by Miransky, Tanabashi, and Yamawaki (1989)[1][2] and William A. Bardeen, Christopher T. Hill, and Manfred Lindner (1990),[3] who connected the theory to the renormalization group, and improved its predictions.

The renormalization group reveals that top quark condensation is fundamentally based upon the ‘infrared fixed point’ for the top quark Higgs-Yukawa coupling, proposed by Pendleton and Ross (1981).[4] and Hill,[5] The ‘infrared’ fixed point originally predicted that the top quark would be heavy, contrary to the prevailing view of the early 1980s. Indeed, the top quark was discovered in 1995 at the large mass of 174 GeV. The infrared-fixed point implies that it is strongly coupled to the Higgs boson at very high energies, corresponding to the Landau pole of the Higgs-Yukawa coupling. At this high scale a bound-state Higgs forms, and in the ‘infrared’, the coupling relaxes to its measured value of order unity by the renormalization group. The Standard Model renormalization group fixed point prediction is about 220 GeV, and the observed top mass is roughly 20% lower than this prediction. The simplest top condensation models are now ruled out by the LHC discovery of the Higgs boson at a mass scale of 125 GeV. However, extended versions of the theory, introducing more particles, can be consistent with the observed top quark and Higgs boson masses.

Future edit

The composite Higgs boson arises naturally in Topcolor models, that are extensions of the standard model using a new force analogous to quantum chromodynamics. To be natural, without excessive fine-tuning (i.e. to stabilize the Higgs mass from large radiative corrections), the theory requires new physics at a relatively low energy scale. Placing new physics at 10 TeV, for instance, the model predicts the top quark to be significantly heavier than observed (at about 600 GeV vs. 171 GeV). Top Seesaw models, also based upon Topcolor, circumvent this difficulty.

The predicted top quark mass comes into improved agreement with the fixed point if there are many additional Higgs scalars beyond the standard model. This may be indicating a rich spectroscopy of new composite Higgs fields at energy scales that can be probed with the LHC and its upgrades.[6][7]

The general idea of a composite Higgs boson, connected in a fundamental way to the top quark, remains compelling, though the full details may not yet be understood.

See also edit

References edit

  1. ^ Miransky, V.A.; Tanabashi, Masaharu; Yamawaki, Koichi (1989). "Dynamical electroweak symmetry breaking with large anomalous dimension and t quark condensate". Physics Letters B. Elsevier BV. 221 (2): 177–183. Bibcode:1989PhLB..221..177M. doi:10.1016/0370-2693(89)91494-9. ISSN 0370-2693.
  2. ^ Miransky, V.A.; Tanabashi, Masaharu; Yamawaki, Koichi (10 June 1989). "Is the t Quark Responsible for the Mass of W and Z Bosons?". Modern Physics Letters A. World Scientific. 04 (11): 1043–1053. Bibcode:1989MPLA....4.1043M. doi:10.1142/s0217732389001210. ISSN 0217-7323.
  3. ^ Bardeen, William A.; Hill, Christopher T. & Lindner, Manfred (1990). "Minimal dynamical symmetry breaking of the standard model". Physical Review D. 41 (5): 1647–1660. Bibcode:1990PhRvD..41.1647B. doi:10.1103/PhysRevD.41.1647. PMID 10012522.
  4. ^ Pendleton, B.; Ross, G.G. (1981). "Mass and mixing angle predictions from infra-red fixed points". Physics Letters B. Elsevier BV. 98 (4): 291–294. Bibcode:1981PhLB...98..291P. doi:10.1016/0370-2693(81)90017-4. ISSN 0370-2693.
  5. ^ Hill, C.T. (1981). "Quark and Lepton masses from Renormalization group fixed points". Physical Review D. 24 (3): 691. Bibcode:1981PhRvD..24..691H. doi:10.1103/PhysRevD.24.691.
  6. ^ Hill, Christopher T.; Machado, Pedro; Thomsen, Anders; Turner, Jessica (2019). "Where are the next Higgs bosons?". Physical Review. D100 (1): 015051. arXiv:1904.04257. Bibcode:2019PhRvD.100a5051H. doi:10.1103/PhysRevD.100.015051. S2CID 104291827.
  7. ^ Hill, Christopher T.; Machado, Pedro; Thomsen, Anders; Turner, Jessica (2019). "Scalar Democracy". Physical Review D. 100 (1): 015015. arXiv:1902.07214. Bibcode:2019PhRvD.100a5015H. doi:10.1103/PhysRevD.100.015015. S2CID 119193325.

December 18, 2023
quark, condensate, particle, physics, quark, condensate, theory, condensation, alternative, standard, model, fundamental, higgs, field, where, higgs, boson, composite, field, composed, quark, antiquark, quark, antiquark, pairs, bound, together, force, called, . In particle physics the top quark condensate theory or top condensation is an alternative to the Standard Model fundamental Higgs field where the Higgs boson is a composite field composed of the top quark and its antiquark The top quark antiquark pairs are bound together by a new force called topcolor analogous to the binding of Cooper pairs in a BCS superconductor or mesons in the strong interactions The top quark is very heavy with a measured mass of approximately 174 GeV comparable to the electroweak scale and so its Yukawa coupling is of order unity suggesting the possibility of strong coupling dynamics at high energy scales This model attempts to explain how the electroweak scale may match the top quark mass Contents 1 History 2 Future 3 See also 4 ReferencesHistory editThe idea was described by Yoichiro Nambu citation needed and subsequently developed by Miransky Tanabashi and Yamawaki 1989 1 2 and William A Bardeen Christopher T Hill and Manfred Lindner 1990 3 who connected the theory to the renormalization group and improved its predictions The renormalization group reveals that top quark condensation is fundamentally based upon the infrared fixed point for the top quark Higgs Yukawa coupling proposed by Pendleton and Ross 1981 4 and Hill 5 The infrared fixed point originally predicted that the top quark would be heavy contrary to the prevailing view of the early 1980s Indeed the top quark was discovered in 1995 at the large mass of 174 GeV The infrared fixed point implies that it is strongly coupled to the Higgs boson at very high energies corresponding to the Landau pole of the Higgs Yukawa coupling At this high scale a bound state Higgs forms and in the infrared the coupling relaxes to its measured value of order unity by the renormalization group The Standard Model renormalization group fixed point prediction is about 220 GeV and the observed top mass is roughly 20 lower than this prediction The simplest top condensation models are now ruled out by the LHC discovery of the Higgs boson at a mass scale of 125 GeV However extended versions of the theory introducing more particles can be consistent with the observed top quark and Higgs boson masses Future editThe composite Higgs boson arises naturally in Topcolor models that are extensions of the standard model using a new force analogous to quantum chromodynamics To be natural without excessive fine tuning i e to stabilize the Higgs mass from large radiative corrections the theory requires new physics at a relatively low energy scale Placing new physics at 10 TeV for instance the model predicts the top quark to be significantly heavier than observed at about 600 GeV vs 171 GeV Top Seesaw models also based upon Topcolor circumvent this difficulty The predicted top quark mass comes into improved agreement with the fixed point if there are many additional Higgs scalars beyond the standard model This may be indicating a rich spectroscopy of new composite Higgs fields at energy scales that can be probed with the LHC and its upgrades 6 7 The general idea of a composite Higgs boson connected in a fundamental way to the top quark remains compelling though the full details may not yet be understood See also editBose Einstein condensation Fermion condensate Hierarchy problem Technicolor physics References edit Miransky V A Tanabashi Masaharu Yamawaki Koichi 1989 Dynamical electroweak symmetry breaking with large anomalous dimension and t quark condensate Physics Letters B Elsevier BV 221 2 177 183 Bibcode 1989PhLB 221 177M doi 10 1016 0370 2693 89 91494 9 ISSN 0370 2693 Miransky V A Tanabashi Masaharu Yamawaki Koichi 10 June 1989 Is the t Quark Responsible for the Mass of W and Z Bosons Modern Physics Letters A World Scientific 04 11 1043 1053 Bibcode 1989MPLA 4 1043M doi 10 1142 s0217732389001210 ISSN 0217 7323 Bardeen William A Hill Christopher T amp Lindner Manfred 1990 Minimal dynamical symmetry breaking of the standard model Physical Review D 41 5 1647 1660 Bibcode 1990PhRvD 41 1647B doi 10 1103 PhysRevD 41 1647 PMID 10012522 Pendleton B Ross G G 1981 Mass and mixing angle predictions from infra red fixed points Physics Letters B Elsevier BV 98 4 291 294 Bibcode 1981PhLB 98 291P doi 10 1016 0370 2693 81 90017 4 ISSN 0370 2693 Hill C T 1981 Quark and Lepton masses from Renormalization group fixed points Physical Review D 24 3 691 Bibcode 1981PhRvD 24 691H doi 10 1103 PhysRevD 24 691 Hill Christopher T Machado Pedro Thomsen Anders Turner Jessica 2019 Where are the next Higgs bosons Physical Review D100 1 015051 arXiv 1904 04257 Bibcode 2019PhRvD 100a5051H doi 10 1103 PhysRevD 100 015051 S2CID 104291827 Hill Christopher T Machado Pedro Thomsen Anders Turner Jessica 2019 Scalar Democracy Physical Review D 100 1 015015 arXiv 1902 07214 Bibcode 2019PhRvD 100a5015H doi 10 1103 PhysRevD 100 015015 S2CID 119193325 Retrieved from https en wikipedia org w index php title Top quark condensate amp oldid 1186235617, wikipedia, wiki, book, books, library,

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