The anomalous magnetic moment of the muon in the Standard Model

T. Aoyama; N. Asmussen; M. Benayoun; J. Bijnens; T. Blum; M. Bruno; I. Caprini; CMC Calame; M. Cè; G. Colangelo; F. Curciarello; H. Czyż; I. Danilkin; M. Davier; C. T.H. Davies; MD Morte; S. I. Eidelman; A. X. El-Khadra; A. Gérardin; D. Giusti; M. Golterman; Steven Gottlieb; V. Gülpers; F. Hagelstein; M. Hayakawa; G. Herdoíza; D. W. Hertzog; A. Hoecker; M. Hoferichter; B. L. Hoid; R. J. Hudspith; F. Ignatov; T. Izubuchi; F. Jegerlehner; L. Jin; A. Keshavarzi; T. Kinoshita; B. Kubis; A. Kupich; A. Kupść; L. Laub; C. Lehner; L. Lellouch; I. Logashenko; B. Malaescu; K. Maltman; M. K. Marinković; P. Masjuan; AS Meyer; HB Meyer; T. Mibe; K. Miura; S. E. Müller; M. Nio; D. Nomura; A. Nyffeler; V. Pascalutsa; M. Passera; EPD Rio; S. Peris; A. Portelli; M. Procura; C. F. Redmer; B. L. Roberts; P. Sánchez-Puertas; S. Serednyakov; B. Shwartz; S. Simula; D. Stöckinger; H. Stöckinger-Kim; P. Stoffer; T. Teubner; RVD Water; M. Vanderhaeghen; G. Venanzoni; GV Hippel; H. Wittig; Z. Zhang; M. N. Achasov; A. Bashir; N. Cardoso; B. Chakraborty; E. H. Chao; J. Charles; A. Crivellin; O. Deineka; A. Denig; DeTa; Craig McNeile

doi:10.1016/j.physrep.2020.07.006

The anomalous magnetic moment of the muon in the Standard Model

T. Aoyama
, N. Asmussen
, M. Benayoun
, J. Bijnens
, T. Blum
, M. Bruno
, I. Caprini
, CMC Calame
, M. Cè
, G. Colangelo^*
, F. Curciarello
, H. Czyż
, I. Danilkin
, M. Davier
, C. T.H. Davies
, MD Morte
, S. I. Eidelman
, A. X. El-Khadra
, A. Gérardin
, D. Giusti

M. Golterman, Steven Gottlieb, V. Gülpers, F. Hagelstein, M. Hayakawa, G. Herdoíza, D. W. Hertzog, A. Hoecker, M. Hoferichter, B. L. Hoid, R. J. Hudspith, F. Ignatov, T. Izubuchi, F. Jegerlehner, L. Jin, A. Keshavarzi, T. Kinoshita, B. Kubis, A. Kupich, A. Kupść, L. Laub, C. Lehner, L. Lellouch, I. Logashenko, B. Malaescu, K. Maltman, M. K. Marinković, P. Masjuan, AS Meyer, HB Meyer, T. Mibe, K. Miura, S. E. Müller, M. Nio, D. Nomura, A. Nyffeler, V. Pascalutsa, M. Passera, EPD Rio, S. Peris, A. Portelli, M. Procura, C. F. Redmer, B. L. Roberts, P. Sánchez-Puertas, S. Serednyakov, B. Shwartz, S. Simula, D. Stöckinger, H. Stöckinger-Kim, P. Stoffer, T. Teubner, RVD Water, M. Vanderhaeghen, G. Venanzoni, GV Hippel, H. Wittig, Z. Zhang, M. N. Achasov, A. Bashir, N. Cardoso, B. Chakraborty, E. H. Chao, J. Charles, A. Crivellin, O. Deineka, A. Denig, DeTa, Craig McNeile

^*Corresponding author for this work

School of Engineering, Computing and Mathematics

High Energy Accelerator Research Organization, Institute of Particle and Nuclear Physics
Nagoya University
RIKEN
University of Southampton
Sorbonne Université
Lund University
University of Connecticut
CERN
Horia Hulubei National Institute of Physics and Nuclear Engineering
Helmholtz Institute Mainz
Johannes Gutenberg University Mainz
University of Bern
National Institute for Nuclear Physics
University of Catania
University of Silesia in Katowice
Université Paris-Saclay
University of Glasgow
Novosibirsk State University
RAS - P.N. Lebedev Physics Institute
Theoretical Physics Department
University of Illinois
CNRS
University of Regensburg
San Francisco State University
Indiana University Bloomington
University of Edinburgh
Universidad Autónoma de Madrid
University of Washington
University of Bonn
Brookhaven National Laboratory Physics Department
Humboldt University of Berlin
University of Manchester
Cornell University
University of Massachusetts
National Centre for Nuclear Research
Uppsala University
University of Adelaide
York University Toronto
Ludwig Maximilian University of Munich
University of Lisbon
Autonomous University of Barcelona
Helmholtz-Zentrum Dresden-Rossendorf
Saitama University
High Energy Accelerator Research Organization, Tsukuba
International University of Health and Welfare
University of Vienna
Boston University
Technische Universität Dresden
University of California at San Diego
University of Liverpool
Universidad Michoacana de San Nicolas de Hidalgo
University of Cambridge
Paul Scherrer Institute
University of Zurich

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Abstract

We review the present status of the Standard Model calculation of the anomalous magnetic moment of the muon. This is performed in a perturbative expansion in the fine-structure constant $\alpha$ and is broken down into pure QED, electroweak, and hadronic contributions. The pure QED contribution is by far the largest and has been evaluated up to and including $\mathcal{O}(\alpha^5)$ with negligible numerical uncertainty. The electroweak contribution is suppressed by $(m_\mu/M_W)^2$ and only shows up at the level of the seventh significant digit. It has been evaluated up to two loops and is known to better than one percent. Hadronic contributions are the most difficult to calculate and are responsible for almost all of the theoretical uncertainty. The leading hadronic contribution appears at $\mathcal{O}(\alpha^2)$ and is due to hadronic vacuum polarization, whereas at $\mathcal{O}(\alpha^3)$ the hadronic light-by-light scattering contribution appears. Given the low characteristic scale of this observable, these contributions have to be calculated with nonperturbative methods, in particular, dispersion relations and the lattice approach to QCD. The largest part of this review is dedicated to a detailed account of recent efforts to improve the calculation of these two contributions with either a data-driven, dispersive approach, or a first-principle, lattice-QCD approach. The final result reads $a_\mu^\text{SM}=116\,591\,810(43)\times 10^{-11}$ and is smaller than the Brookhaven measurement by 3.7$\sigma$. The experimental uncertainty will soon be reduced by up to a factor four by the new experiment currently running at Fermilab, and also by the future J-PARC experiment. This and the prospects to further reduce the theoretical uncertainty in the near future-which are also discussed here-make this quantity one of the most promising places to look for evidence of new physics.

Original language	English
Number of pages	0
Journal	Physics Reports
Volume	0
Issue number	0
Early online date	14 Aug 2020
DOIs	https://doi.org/10.1016/j.physrep.2020.07.006
Publication status	Published - 14 Aug 2020

Keywords

hep-ph
hep-ex
hep-lat
nucl-ex
nucl-th

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10.1016/j.physrep.2020.07.006

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Aoyama, T., Asmussen, N., Benayoun, M., Bijnens, J., Blum, T., Bruno, M., Caprini, I., Calame, CMC., Cè, M., Colangelo, G., Curciarello, F., Czyż, H., Danilkin, I., Davier, M., Davies, C. T. H., Morte, MD., Eidelman, S. I., El-Khadra, A. X., Gérardin, A., ... McNeile, C. (2020). The anomalous magnetic moment of the muon in the Standard Model. Physics Reports, 0(0). https://doi.org/10.1016/j.physrep.2020.07.006

@article{ac16b6cc89954e86893200321454fd10,

title = "The anomalous magnetic moment of the muon in the Standard Model",

abstract = "We review the present status of the Standard Model calculation of the anomalous magnetic moment of the muon. This is performed in a perturbative expansion in the fine-structure constant \$\textbackslash{}alpha\$ and is broken down into pure QED, electroweak, and hadronic contributions. The pure QED contribution is by far the largest and has been evaluated up to and including \$\textbackslash{}mathcal\{O\}(\textbackslash{}alpha\textasciicircum{}5)\$ with negligible numerical uncertainty. The electroweak contribution is suppressed by \$(m\_\textbackslash{}mu/M\_W)\textasciicircum{}2\$ and only shows up at the level of the seventh significant digit. It has been evaluated up to two loops and is known to better than one percent. Hadronic contributions are the most difficult to calculate and are responsible for almost all of the theoretical uncertainty. The leading hadronic contribution appears at \$\textbackslash{}mathcal\{O\}(\textbackslash{}alpha\textasciicircum{}2)\$ and is due to hadronic vacuum polarization, whereas at \$\textbackslash{}mathcal\{O\}(\textbackslash{}alpha\textasciicircum{}3)\$ the hadronic light-by-light scattering contribution appears. Given the low characteristic scale of this observable, these contributions have to be calculated with nonperturbative methods, in particular, dispersion relations and the lattice approach to QCD. The largest part of this review is dedicated to a detailed account of recent efforts to improve the calculation of these two contributions with either a data-driven, dispersive approach, or a first-principle, lattice-QCD approach. The final result reads \$a\_\textbackslash{}mu\textasciicircum{}\textbackslash{}text\{SM\}=116\textbackslash{},591\textbackslash{},810(43)\textbackslash{}times 10\textasciicircum{}\{-11\}\$ and is smaller than the Brookhaven measurement by 3.7\$\textbackslash{}sigma\$. The experimental uncertainty will soon be reduced by up to a factor four by the new experiment currently running at Fermilab, and also by the future J-PARC experiment. This and the prospects to further reduce the theoretical uncertainty in the near future-which are also discussed here-make this quantity one of the most promising places to look for evidence of new physics.",

keywords = "hep-ph, hep-ex, hep-lat, nucl-ex, nucl-th",

author = "T. Aoyama and N. Asmussen and M. Benayoun and J. Bijnens and T. Blum and M. Bruno and I. Caprini and CMC Calame and M. C{\`e} and G. Colangelo and F. Curciarello and H. Czy{\.z} and I. Danilkin and M. Davier and Davies, \{C. T.H.\} and MD Morte and Eidelman, \{S. I.\} and El-Khadra, \{A. X.\} and A. G{\'e}rardin and D. Giusti and M. Golterman and Steven Gottlieb and V. G{\"u}lpers and F. Hagelstein and M. Hayakawa and G. Herdo{\'i}za and Hertzog, \{D. W.\} and A. Hoecker and M. Hoferichter and Hoid, \{B. L.\} and Hudspith, \{R. J.\} and F. Ignatov and T. Izubuchi and F. Jegerlehner and L. Jin and A. Keshavarzi and T. Kinoshita and B. Kubis and A. Kupich and A. Kup{\'s}{\'c} and L. Laub and C. Lehner and L. Lellouch and I. Logashenko and B. Malaescu and K. Maltman and Marinkovi{\'c}, \{M. K.\} and P. Masjuan and AS Meyer and HB Meyer and T. Mibe and K. Miura and M{\"u}ller, \{S. E.\} and M. Nio and D. Nomura and A. Nyffeler and V. Pascalutsa and M. Passera and EPD Rio and S. Peris and A. Portelli and M. Procura and Redmer, \{C. F.\} and Roberts, \{B. L.\} and P. S{\'a}nchez-Puertas and S. Serednyakov and B. Shwartz and S. Simula and D. St{\"o}ckinger and H. St{\"o}ckinger-Kim and P. Stoffer and T. Teubner and RVD Water and M. Vanderhaeghen and G. Venanzoni and GV Hippel and H. Wittig and Z. Zhang and Achasov, \{M. N.\} and A. Bashir and N. Cardoso and B. Chakraborty and Chao, \{E. H.\} and J. Charles and A. Crivellin and O. Deineka and A. Denig and DeTa and Craig McNeile",

year = "2020",

month = aug,

day = "14",

doi = "10.1016/j.physrep.2020.07.006",

language = "English",

volume = "0",

journal = "Physics Reports",

issn = "0370-1573",

publisher = "Elsevier B.V.",

number = "0",

}

Aoyama, T, Asmussen, N, Benayoun, M, Bijnens, J, Blum, T, Bruno, M, Caprini, I, Calame, CMC, Cè, M, Colangelo, G, Curciarello, F, Czyż, H, Danilkin, I, Davier, M, Davies, CTH, Morte, MD, Eidelman, SI, El-Khadra, AX, Gérardin, A, Giusti, D, Golterman, M, Gottlieb, S, Gülpers, V, Hagelstein, F, Hayakawa, M, Herdoíza, G, Hertzog, DW, Hoecker, A, Hoferichter, M, Hoid, BL, Hudspith, RJ, Ignatov, F, Izubuchi, T, Jegerlehner, F, Jin, L, Keshavarzi, A, Kinoshita, T, Kubis, B, Kupich, A, Kupść, A, Laub, L, Lehner, C, Lellouch, L, Logashenko, I, Malaescu, B, Maltman, K, Marinković, MK, Masjuan, P, Meyer, AS, Meyer, HB, Mibe, T, Miura, K, Müller, SE, Nio, M, Nomura, D, Nyffeler, A, Pascalutsa, V, Passera, M, Rio, EPD, Peris, S, Portelli, A, Procura, M, Redmer, CF, Roberts, BL, Sánchez-Puertas, P, Serednyakov, S, Shwartz, B, Simula, S, Stöckinger, D, Stöckinger-Kim, H, Stoffer, P, Teubner, T, Water, RVD, Vanderhaeghen, M, Venanzoni, G, Hippel, GV, Wittig, H, Zhang, Z, Achasov, MN, Bashir, A, Cardoso, N, Chakraborty, B, Chao, EH, Charles, J, Crivellin, A, Deineka, O, Denig, A, DeTa, & McNeile, C 2020, 'The anomalous magnetic moment of the muon in the Standard Model', Physics Reports, vol. 0, no. 0. https://doi.org/10.1016/j.physrep.2020.07.006

TY - JOUR

T1 - The anomalous magnetic moment of the muon in the Standard Model

AU - Aoyama, T.

AU - Asmussen, N.

AU - Benayoun, M.

AU - Bijnens, J.

AU - Blum, T.

AU - Bruno, M.

AU - Caprini, I.

AU - Calame, CMC

AU - Cè, M.

AU - Colangelo, G.

AU - Curciarello, F.

AU - Czyż, H.

AU - Danilkin, I.

AU - Davier, M.

AU - Davies, C. T.H.

AU - Morte, MD

AU - Eidelman, S. I.

AU - El-Khadra, A. X.

AU - Gérardin, A.

AU - Giusti, D.

AU - Golterman, M.

AU - Gottlieb, Steven

AU - Gülpers, V.

AU - Hagelstein, F.

AU - Hayakawa, M.

AU - Herdoíza, G.

AU - Hertzog, D. W.

AU - Hoecker, A.

AU - Hoferichter, M.

AU - Hoid, B. L.

AU - Hudspith, R. J.

AU - Ignatov, F.

AU - Izubuchi, T.

AU - Jegerlehner, F.

AU - Jin, L.

AU - Keshavarzi, A.

AU - Kinoshita, T.

AU - Kubis, B.

AU - Kupich, A.

AU - Kupść, A.

AU - Laub, L.

AU - Lehner, C.

AU - Lellouch, L.

AU - Logashenko, I.

AU - Malaescu, B.

AU - Maltman, K.

AU - Marinković, M. K.

AU - Masjuan, P.

AU - Meyer, AS

AU - Meyer, HB

AU - Mibe, T.

AU - Miura, K.

AU - Müller, S. E.

AU - Nio, M.

AU - Nomura, D.

AU - Nyffeler, A.

AU - Pascalutsa, V.

AU - Passera, M.

AU - Rio, EPD

AU - Peris, S.

AU - Portelli, A.

AU - Procura, M.

AU - Redmer, C. F.

AU - Roberts, B. L.

AU - Sánchez-Puertas, P.

AU - Serednyakov, S.

AU - Shwartz, B.

AU - Simula, S.

AU - Stöckinger, D.

AU - Stöckinger-Kim, H.

AU - Stoffer, P.

AU - Teubner, T.

AU - Water, RVD

AU - Vanderhaeghen, M.

AU - Venanzoni, G.

AU - Hippel, GV

AU - Wittig, H.

AU - Zhang, Z.

AU - Achasov, M. N.

AU - Bashir, A.

AU - Cardoso, N.

AU - Chakraborty, B.

AU - Chao, E. H.

AU - Charles, J.

AU - Crivellin, A.

AU - Deineka, O.

AU - Denig, A.

AU - DeTa, null

AU - McNeile, Craig

PY - 2020/8/14

Y1 - 2020/8/14

N2 - We review the present status of the Standard Model calculation of the anomalous magnetic moment of the muon. This is performed in a perturbative expansion in the fine-structure constant $\alpha$ and is broken down into pure QED, electroweak, and hadronic contributions. The pure QED contribution is by far the largest and has been evaluated up to and including $\mathcal{O}(\alpha^5)$ with negligible numerical uncertainty. The electroweak contribution is suppressed by $(m_\mu/M_W)^2$ and only shows up at the level of the seventh significant digit. It has been evaluated up to two loops and is known to better than one percent. Hadronic contributions are the most difficult to calculate and are responsible for almost all of the theoretical uncertainty. The leading hadronic contribution appears at $\mathcal{O}(\alpha^2)$ and is due to hadronic vacuum polarization, whereas at $\mathcal{O}(\alpha^3)$ the hadronic light-by-light scattering contribution appears. Given the low characteristic scale of this observable, these contributions have to be calculated with nonperturbative methods, in particular, dispersion relations and the lattice approach to QCD. The largest part of this review is dedicated to a detailed account of recent efforts to improve the calculation of these two contributions with either a data-driven, dispersive approach, or a first-principle, lattice-QCD approach. The final result reads $a_\mu^\text{SM}=116\,591\,810(43)\times 10^{-11}$ and is smaller than the Brookhaven measurement by 3.7$\sigma$. The experimental uncertainty will soon be reduced by up to a factor four by the new experiment currently running at Fermilab, and also by the future J-PARC experiment. This and the prospects to further reduce the theoretical uncertainty in the near future-which are also discussed here-make this quantity one of the most promising places to look for evidence of new physics.

AB - We review the present status of the Standard Model calculation of the anomalous magnetic moment of the muon. This is performed in a perturbative expansion in the fine-structure constant $\alpha$ and is broken down into pure QED, electroweak, and hadronic contributions. The pure QED contribution is by far the largest and has been evaluated up to and including $\mathcal{O}(\alpha^5)$ with negligible numerical uncertainty. The electroweak contribution is suppressed by $(m_\mu/M_W)^2$ and only shows up at the level of the seventh significant digit. It has been evaluated up to two loops and is known to better than one percent. Hadronic contributions are the most difficult to calculate and are responsible for almost all of the theoretical uncertainty. The leading hadronic contribution appears at $\mathcal{O}(\alpha^2)$ and is due to hadronic vacuum polarization, whereas at $\mathcal{O}(\alpha^3)$ the hadronic light-by-light scattering contribution appears. Given the low characteristic scale of this observable, these contributions have to be calculated with nonperturbative methods, in particular, dispersion relations and the lattice approach to QCD. The largest part of this review is dedicated to a detailed account of recent efforts to improve the calculation of these two contributions with either a data-driven, dispersive approach, or a first-principle, lattice-QCD approach. The final result reads $a_\mu^\text{SM}=116\,591\,810(43)\times 10^{-11}$ and is smaller than the Brookhaven measurement by 3.7$\sigma$. The experimental uncertainty will soon be reduced by up to a factor four by the new experiment currently running at Fermilab, and also by the future J-PARC experiment. This and the prospects to further reduce the theoretical uncertainty in the near future-which are also discussed here-make this quantity one of the most promising places to look for evidence of new physics.

KW - hep-ph

KW - hep-ex

KW - hep-lat

KW - nucl-ex

KW - nucl-th

UR - https://pearl.plymouth.ac.uk/secam-research/2022/

U2 - 10.1016/j.physrep.2020.07.006

DO - 10.1016/j.physrep.2020.07.006

M3 - Article

SN - 0370-1573

VL - 0

JO - Physics Reports

JF - Physics Reports

IS - 0

ER -

The anomalous magnetic moment of the muon in the Standard Model

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