The strong coupling constant: state of the art and the decade ahead

QCD; M. A. Benitez-Rathgeb; D. Boito; A. H. Hoang

doi:10.48550/arXiv.2203.08271

The strong coupling constant: state of the art and the decade ahead

QCD
, M. A. Benitez-Rathgeb
, D. Boito
, A. H. Hoang

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Theoretical predictions for particle production cross sections and decays at colliders rely heavily on perturbative Quantum Chromodynamics (QCD) calculations, expressed as an expansion in powers of the strong coupling constant α S . The current O ( 1 % ) uncertainty of the QCD coupling evaluated at the reference Z boson mass, α S ( m Z 2 ) = 0.1179 ± 0.0009 , is one of the limiting factors to more precisely describe multiple processes at current and future colliders. A reduction of this uncertainty is thus a prerequisite to perform precision tests of the Standard Model as well as searches for new physics. This report provides a comprehensive summary of the state-of-the-art, challenges, and prospects in the experimental and theoretical study of the strong coupling. The current α S ( m Z 2 ) world average is derived from a combination of seven categories of observables: (i) lattice QCD, (ii) hadronic τ decays, (iii) deep-inelastic scattering and parton distribution functions fits, (iv) electroweak boson decays, hadronic final-states in (v) e+e−, (vi) e-p, and (vii) p-p collisions, and (viii) quarkonia decays and masses. We review the current status of each of these seven α S ( m Z 2 ) extraction methods, discuss novel α S determinations, and examine the averaging method used to obtain the world-average value. Each of the methods discussed provides a ‘wish list’ of experimental and theoretical developments required in order to achieve the goal of a per-mille precision on α S ( m Z 2 ) within the next decade.

Original language	English
Article number	090501
Number of pages	163
Journal	Journal of Physics G: Nuclear and Particle Physics
Volume	51
Issue number	9
DOIs	https://doi.org/10.48550/arXiv.2203.08271 https://doi.org/10.1088/1361-6471/ad1a78
Publication status	Published - Sept 2024

Funding

Acknowledgments\u2014 DB thanks the Universidad de Salamanca and VM thanks the Sao Carlos Physics Institute at Universidade de S\u00E3o Paulo, for hospitality. This work was supported by the FAPESP-USAL SPRINT Grant No. 2018/14967-4. DB\u2019s work is supported by the S\u00E3o Paulo Research Foundation (FAPESP) Grants No. 2021/06756-6, the Coordena\u00E7\u00E3o de Aperfei\u00E7oamento de Pessoal de N\u00EDvel Superior\u2014Brasil (CAPES)\u2014Finance Code 001, and by CNPq grant No. 309847/2018-4. VM is supported by the MECD grant PID2019-105439GB-C22, the EU STRONG-2020 project under the program H2020-INFRAIA-2018-1, grant agreement No. 824 093 and the COST Action CA16201 PARTICLEFACE. Acknowledgments\u2014I thank my colleagues in the FLAG \u03B1 -WG, Peter Petreczky and Roger Horsley for the pleasant collaboration and feedback on a draft of this contribution. Partial support by the EU unter grant agreement H2020-MSCA-ITN-2018-813942 (EuroPLEx) is gratefully acknowledged. S Acknowledgments\u2014This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Nuclear Physics under contract DE-AC05-06OR23177. Acknowledgments\u2014VM is supported by the MECD grant PID2019-105439GB-C22, the EU STRONG-2020 project under the program H2020-INFRAIA-2018-1, grant agreement No. 824 093 and the COST Action CA16201 PARTICLEFACE. Acknowledgments\u2014PP was supported by US Department of Energy under Contract No. DE-SC0012704. JHW\u2019s research was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation)\u2013Projektnummer 417 533 893/GRK2575 \u2018Rethinking Quantum Field Theory\u2019. Support from the EU STRONG-2020 project under the program H2020-INFRAIA-2018-1, grant agreement No. 824093 is acknowledged. Acknowledgments\u2014This work has been supported by MCIN/AEI/10.13039/501100011033, Grant No. PID2020-114473GB-I00, by the Generalitat Valenciana, Grant No. Prometeo/2021/071, and by the Agence Nationale de la Recherche (ANR), Grant ANR-19-CE31-0012 (project MORA). Acknowledgments\u2014TC would like to thank the Science and Technology Facilities Council (STFC) for support via grant awards ST/P000274/1 and ST/T000856/1. Acknowledgments\u2014 PP was supported by U.S. Department of Energy under Contract No. DE-SC0012704. JHW's research was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) - Projektnummer 417 533 893/GRK2575 \u2018Rethinking Quantum Field Theory\u2019.

Austrian Fields of Science 2012

103012 High energy physics

Keywords

colliders
QCD
strong coupling

Access to Document

10.48550/arXiv.2203.08271Licence: CC BY-NC-ND 4.0
10.1088/1361-6471/ad1a78Licence: CC BY 4.0

Cite this

@article{b6bdaebaa0194c6cafd98595ef715602,

title = "The strong coupling constant: state of the art and the decade ahead",

abstract = "Theoretical predictions for particle production cross sections and decays at colliders rely heavily on perturbative Quantum Chromodynamics (QCD) calculations, expressed as an expansion in powers of the strong coupling constant α S . The current O ( 1 \% ) uncertainty of the QCD coupling evaluated at the reference Z boson mass, α S ( m Z 2 ) = 0.1179 ± 0.0009 , is one of the limiting factors to more precisely describe multiple processes at current and future colliders. A reduction of this uncertainty is thus a prerequisite to perform precision tests of the Standard Model as well as searches for new physics. This report provides a comprehensive summary of the state-of-the-art, challenges, and prospects in the experimental and theoretical study of the strong coupling. The current α S ( m Z 2 ) world average is derived from a combination of seven categories of observables: (i) lattice QCD, (ii) hadronic τ decays, (iii) deep-inelastic scattering and parton distribution functions fits, (iv) electroweak boson decays, hadronic final-states in (v) e+e−, (vi) e-p, and (vii) p-p collisions, and (viii) quarkonia decays and masses. We review the current status of each of these seven α S ( m Z 2 ) extraction methods, discuss novel α S determinations, and examine the averaging method used to obtain the world-average value. Each of the methods discussed provides a {\textquoteleft}wish list{\textquoteright} of experimental and theoretical developments required in order to achieve the goal of a per-mille precision on α S ( m Z 2 ) within the next decade.",

keywords = "colliders, QCD, strong coupling",

author = "QCD and D. d{\textquoteright}Enterria and S. Kluth and G. Zanderighi and C. Ayala and Benitez-Rathgeb, \{M. A.\} and J. Bl{\"u}mlein and D. Boito and N. Brambilla and D. Britzger and S. Camarda and Cooper-Sarkar, \{A. M.\} and T. Cridge and G. Cveti{\v c} and D. d{\textquoteright}Enterria and \{Dalla Brida\}, M. and A. Deur and F. Giuli and M. Golterman and Hoang, \{A. H.\} and J. Huston and M. Jamin and S. Kluth and Kotikov, \{A. V.\} and Krivokhizhin, \{V. G.\} and Kronfeld, \{A. S.\} and V. Leino and K. Lipka and T. M{\"a}kel{\"a} and B. Malaescu and K. Maltman and S. Marzani and V. Mateu and S. Moch and Monni, \{P. F.\} and P. Nadolsky and P. Nason and Nesterenko, \{A. V.\} and R. P{\'e}rez-Ramos and S. Peris and P. Petreczky and A. Pich and K. Rabbertz and A. Ramos and D. Reichelt and A. Rodriguez-S{\'a}nchez and J. Rojo and M. Saragnese and L. Sawyer and M. Schott and S. Schumann",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Published by IOP Publishing Ltd.",

year = "2024",

month = sep,

doi = "10.48550/arXiv.2203.08271",

language = "English",

volume = "51",

journal = "Journal of Physics G: Nuclear and Particle Physics",

issn = "0954-3899",

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number = "9",

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TY - JOUR

T1 - The strong coupling constant: state of the art and the decade ahead

AU - QCD

AU - d’Enterria, D.

AU - Kluth, S.

AU - Zanderighi, G.

AU - Ayala, C.

AU - Benitez-Rathgeb, M. A.

AU - Blümlein, J.

AU - Boito, D.

AU - Brambilla, N.

AU - Britzger, D.

AU - Camarda, S.

AU - Cooper-Sarkar, A. M.

AU - Cridge, T.

AU - Cvetič, G.

AU - d’Enterria, D.

AU - Dalla Brida, M.

AU - Deur, A.

AU - Giuli, F.

AU - Golterman, M.

AU - Hoang, A. H.

AU - Huston, J.

AU - Jamin, M.

AU - Kluth, S.

AU - Kotikov, A. V.

AU - Krivokhizhin, V. G.

AU - Kronfeld, A. S.

AU - Leino, V.

AU - Lipka, K.

AU - Mäkelä, T.

AU - Malaescu, B.

AU - Maltman, K.

AU - Marzani, S.

AU - Mateu, V.

AU - Moch, S.

AU - Monni, P. F.

AU - Nadolsky, P.

AU - Nason, P.

AU - Nesterenko, A. V.

AU - Pérez-Ramos, R.

AU - Peris, S.

AU - Petreczky, P.

AU - Pich, A.

AU - Rabbertz, K.

AU - Ramos, A.

AU - Reichelt, D.

AU - Rodriguez-Sánchez, A.

AU - Rojo, J.

AU - Saragnese, M.

AU - Sawyer, L.

AU - Schott, M.

AU - Schumann, S.

PY - 2024/9

Y1 - 2024/9

N2 - Theoretical predictions for particle production cross sections and decays at colliders rely heavily on perturbative Quantum Chromodynamics (QCD) calculations, expressed as an expansion in powers of the strong coupling constant α S . The current O ( 1 % ) uncertainty of the QCD coupling evaluated at the reference Z boson mass, α S ( m Z 2 ) = 0.1179 ± 0.0009 , is one of the limiting factors to more precisely describe multiple processes at current and future colliders. A reduction of this uncertainty is thus a prerequisite to perform precision tests of the Standard Model as well as searches for new physics. This report provides a comprehensive summary of the state-of-the-art, challenges, and prospects in the experimental and theoretical study of the strong coupling. The current α S ( m Z 2 ) world average is derived from a combination of seven categories of observables: (i) lattice QCD, (ii) hadronic τ decays, (iii) deep-inelastic scattering and parton distribution functions fits, (iv) electroweak boson decays, hadronic final-states in (v) e+e−, (vi) e-p, and (vii) p-p collisions, and (viii) quarkonia decays and masses. We review the current status of each of these seven α S ( m Z 2 ) extraction methods, discuss novel α S determinations, and examine the averaging method used to obtain the world-average value. Each of the methods discussed provides a ‘wish list’ of experimental and theoretical developments required in order to achieve the goal of a per-mille precision on α S ( m Z 2 ) within the next decade.

AB - Theoretical predictions for particle production cross sections and decays at colliders rely heavily on perturbative Quantum Chromodynamics (QCD) calculations, expressed as an expansion in powers of the strong coupling constant α S . The current O ( 1 % ) uncertainty of the QCD coupling evaluated at the reference Z boson mass, α S ( m Z 2 ) = 0.1179 ± 0.0009 , is one of the limiting factors to more precisely describe multiple processes at current and future colliders. A reduction of this uncertainty is thus a prerequisite to perform precision tests of the Standard Model as well as searches for new physics. This report provides a comprehensive summary of the state-of-the-art, challenges, and prospects in the experimental and theoretical study of the strong coupling. The current α S ( m Z 2 ) world average is derived from a combination of seven categories of observables: (i) lattice QCD, (ii) hadronic τ decays, (iii) deep-inelastic scattering and parton distribution functions fits, (iv) electroweak boson decays, hadronic final-states in (v) e+e−, (vi) e-p, and (vii) p-p collisions, and (viii) quarkonia decays and masses. We review the current status of each of these seven α S ( m Z 2 ) extraction methods, discuss novel α S determinations, and examine the averaging method used to obtain the world-average value. Each of the methods discussed provides a ‘wish list’ of experimental and theoretical developments required in order to achieve the goal of a per-mille precision on α S ( m Z 2 ) within the next decade.

KW - colliders

KW - QCD

KW - strong coupling

UR - https://www.scopus.com/pages/publications/85208751586

U2 - 10.48550/arXiv.2203.08271

DO - 10.48550/arXiv.2203.08271

M3 - Article

AN - SCOPUS:85208751586

SN - 0954-3899

VL - 51

JO - Journal of Physics G: Nuclear and Particle Physics

JF - Journal of Physics G: Nuclear and Particle Physics

IS - 9

M1 - 090501

ER -

The strong coupling constant: state of the art and the decade ahead

Abstract

Funding

Austrian Fields of Science 2012

Keywords

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