PHYSICAL REVIEW D 98, 030001 (2018) 1
REVIEW OF PARTICLE PHYSICS*
Particle Data Group
Abstract
The Review summarizes much of particle physics and cosmology. Using data from previous editions, plus 2,873 new measurements from 758 papers, we list, evaluate, and average measured properties of gauge bosons and the recently discovered Higgs boson, leptons, quarks, mesons, and baryons. We summarize searches for hypothetical particles such as supersymmetric particles, heavy bosons, axions, dark photons, etc. Particle properties and search limits are listed in Summary Tables. We give numerous tables, figures, formulae, and reviews of topics such as Higgs Boson Physics, Supersymmetry, Grand Unified Theories, Neutrino Mixing, Dark Energy, Dark Matter, Cosmology, Particle Detectors, Colliders, Probability and Statistics. Among the 118 reviews are many that are new or heavily revised, including a new review on Neutrinos in Cosmology.
Starting with this edition, the Review is divided into two volumes. Volume 1 includes the Summary Tables and all review articles. Volume 2 consists of the Particle Listings. Review articles that were previously part of the Listings are now included in volume 1.
The complete Review (both volumes) is published online on the website of the Particle Data Group (http://pdg.lbl.gov) and in a journal. Volume 1 is available in print as the PDG Book. A Particle Physics Booklet with the Summary Tables and essential tables, figures, and equations from selected review articles is also available.
DOI: 10.1103/PhysRevD.98.030001
The 2018 edition of the Review of Particle Physics should be cited as:
M. Tanabashi et al. (Particle Data Group), Phys. Rev. D 98, 030001 (2018)
c
°2018 Regents of the University of California
∗The publication of the Review of Particle Physics is supported by the Director, Office of Science, Office of High Energy Physics of the U.S. Department of Energy under Contract No. DE–AC02–05CH11231; by the European Laboratory for Particle Physics (CERN); by an implementing arrangement between the governments of Japan (MEXT: Ministry of Education, Culture, Sports, Science and Technology) and the United States (DOE) on cooperative research and development; and by the Italian National Institute of Nuclear Physics (INFN). Individual collaborators receive support for their PDG activities from their respective funding agencies.
2
Particle Data Group
M. Tanabashi,
1,2K. Hagiwara,
3K. Hikasa,
4K. Nakamura,
5,3Y. Sumino,
4F. Takahashi,
4J. Tanaka,
6K. Agashe,
7G. Aielli,
8C. Amsler,
9M. Antonelli,
10D.M. Asner,
11H. Baer,
12Sw. Banerjee,
13R.M. Barnett,
14T. Basaglia,
15C.W. Bauer,
14J.J. Beatty,
16V.I. Belousov,
17J. Beringer,
14S. Bethke,
18A. Bettini,
19* H. Bichsel,
20O. Biebel,
21K.M. Black,
22E. Blucher,
23O. Buchmuller,
24V. Burkert,
25M.A. Bychkov,
26R.N. Cahn,
14M. Carena,
27,23,28A. Ceccucci,
15A. Cerri,
29D. Chakraborty,
30M.-C. Chen,
31R.S. Chivukula,
32G. Cowan,
33O. Dahl,
14G. D’Ambrosio,
34T. Damour,
35D. de Florian,
36A. de Gouvˆea,
37T. DeGrand,
38P. de Jong,
39G. Dissertori,
40B.A. Dobrescu,
27M. D’Onofrio,
41M. Doser,
15M. Drees,
42H.K. Dreiner,
42D.A. Dwyer,
14P. Eerola,
43S. Eidelman,
44,45J. Ellis,
46,15J. Erler,
47V.V. Ezhela,
17W. Fetscher,
40B.D. Fields,
48,49R. Firestone,
50B. Foster,
51,52,53A. Freitas,
54H. Gallagher,
55L. Garren,
27H.-J. Gerber,
40G. Gerbier,
56T. Gershon,
57Y. Gershtein,
58T. Gherghetta,
59A.A. Godizov,
17M. Goodman,
60C. Grab,
40A.V. Gritsan,
61C. Grojean,
62,63D.E. Groom,
14M. Gr¨ unewald,
64A. Gurtu,
65,15T. Gutsche,
66H.E. Haber,
67C. Hanhart,
68S. Hashimoto,
3Y. Hayato,
69K.G. Hayes,
70A. Hebecker,
71S. Heinemeyer,
72,73,74B. Heltsley,
75J. J. Hern´andez-Rey,
76†J. Hisano,
2A. H¨ocker,
15J. Holder,
77,78A. Holtkamp,
15T. Hyodo,
79K.D. Irwin,
80,81K.F. Johnson,
82M. Kado,
83,15M. Karliner,
84U.F. Katz,
85S.R. Klein,
50E. Klempt,
86R.V. Kowalewski,
87F. Krauss,
88M. Kreps,
57B. Krusche,
89Yu.V. Kuyanov,
17‡Y. Kwon,
90O. Lahav,
91J. Laiho,
92J. Lesgourgues,
93A. Liddle,
94Z. Ligeti,
14C.-J. Lin,
14C. Lippmann,
95T.M. Liss,
96L. Littenberg,
11K.S. Lugovsky,
14,17S.B. Lugovsky,
17A. Lusiani,
97,98Y. Makida,
3F. Maltoni,
99T. Mannel,
100A.V. Manohar,
101W.J. Marciano,
11A.D. Martin,
88A. Masoni,
102J. Matthews,
103U.-G. Meißner,
86,68D. Milstead,
104R.E. Mitchell,
105K. M¨onig,
106P. Molaro,
107F. Moortgat,
15,108M. Moskovic,
15H. Murayama,
5,109,14M. Narain,
110P. Nason,
111S. Navas,
112†M. Neubert,
113P. Nevski,
11§ Y. Nir,
114K.A. Olive,
59S. Pagan Griso,
14J. Parsons,
115C. Patrignani,
116J.A. Peacock,
94M. Pennington,
25S.T. Petcov,
117,5,118V.A. Petrov,
17E. Pianori,
14A. Piepke,
119A. Pomarol,
120,121A. Quadt,
122J. Rademacker,
123G. Raffelt,
124B.N. Ratcliff,
81P. Richardson,
88A. Ringwald,
52S. Roesler,
15S. Rolli,
125A. Romaniouk,
126L.J. Rosenberg,
20J.L. Rosner,
23G. Rybka,
20R.A. Ryutin,
17C.T. Sachrajda,
127Y. Sakai,
3G.P. Salam,
15,128,129S. Sarkar,
129,130F. Sauli,
15§ O. Schneider,
131K. Scholberg,
132A.J. Schwartz,
133D. Scott,
134V. Sharma,
101S.R. Sharpe,
20T. Shutt,
81M. Silari,
15T. Sj¨ostrand,
135P. Skands,
136T. Skwarnicki,
92J.G. Smith,
38G.F. Smoot,
137,109,14S. Spanier,
138H. Spieler,
14§ C. Spiering,
106A. Stahl,
139S.L. Stone,
92T. Sumiyoshi,
140M.J. Syphers,
30,27K. Terashi,
69J. Terning,
141U. Thoma,
86R.S. Thorne,
91L. Tiator,
142M. Titov,
56N.P. Tkachenko,
17N.A. T¨ornqvist,
43‡D.R. Tovey,
143G. Valencia,
136R. Van de Water,
27N. Varelas,
144G. Venanzoni,
98L. Verde,
145,146M.G. Vincter,
147P. Vogel,
148A. Vogt,
149S.P. Wakely,
23,28W. Walkowiak,
100C.W. Walter,
132D. Wands,
150D.R. Ward,
151M.O. Wascko,
24G. Weiglein,
52D.H. Weinberg,
152E.J. Weinberg,
115M. White,
109,14L.R. Wiencke,
153S. Willocq,
154C.G. Wohl,
14J. Womersley,
155C.L. Woody,
11R.L. Workman,
156W.-M. Yao,
14G.P. Zeller,
27O.V. Zenin,
17,157R.-Y. Zhu,
158S.-L. Zhu,
159F. Zimmermann,
15P.A. Zyla
14Technical Associates: J. Anderson,
14L. Fuller,
14kV.S. Lugovsky,
17P. Schaffner
141.
Department of Physics, Nagoya University, Nagoya, Japan2.
Nagoya University, Kobayashi-Maskawa Institute, Nagoya, Japan3.
KEK, High Energy Accelerator Research Organization, Tsukuba, Japan4.
Tohoku University, Department of Physics, Sendai, Japan5.
University of Tokyo, Kavli IPMU (WPI), The University of Tokyo Institutes for Advanced Study, Kashiwa, Japan6.
International Center for Elementary Particle Physics (ICEPP), University of Tokyo, Tokyo, Japan7.
University of Maryland, Department of Physics, College Park, MD, United States of America8.
Universit`a degli Studi di Roma ”Tor Vergata”, Rome, Italy9.
Stefan Meyer Institute for Subatomic Physics, Austrian Academy of Sciences, Vienna, Austria10.
Lab. Nazionali di Frascati dell’INFN, Frascati, Italy11.
Brookhaven National Laboratory, Nuclear and Particle Physics Directorate, Upton, NY, United States of America12.
University of Oklahoma, Department of Physics and Astronomy, Norman, OK, United States of America13.
University of Louisville, Louisville, KY, United States of America14.
Physics Division, Lawrence Berkeley National Laboratory, Berkeley, CA, United States of America15.
CERN, European Organization for Nuclear Research, Gen`eve, Switzerland16.
Ohio State University, Department of Physics, Columbus, OH, United States of America17.
Institute for High Energy Physics, COMPAS Group, Protvino, Russian Federation18.
Max-Planck-Institute of Physics, Munich, Germany19.
INFN and Dipartimento di Fisica, Universit`a di Padova, Padova, Italy* Coordination activities supported directly by INFN.
†Support from Plan Estatal de Investigacion MINECO, Spain and ERDF of the European Union (FPA2015-06150-C3).
‡Deceased.
§ Retired.
kSupported by the U.S. Department of Energy, Office of Science, Office of Workforce Development for Teachers and Scientists (WDTS) under the Science Undergraduate Laboratory Internship (SULI) program.
3
20.
University of Washington, Department of Physics, Seattle, WA, United States of America21.
Ludwig-Maximilians-Universit¨at, Fakult¨at f¨ur Physik, M¨unchen, Germany22.
Boston University, Department of Physics, Boston, MA, United States of America23.
University of Chicago, Enrico Fermi Institute and Department of Physics, Chicago, IL, United States of America24.
Imperial College, High Energy Physics Group, Blackett Laboratory, London, United Kingdom25.
Jefferson Lab, Newport News, VA, United States of America26.
University of Virginia, Department of Physics, Charlottesville, VA, United States of America27.
Fermi National Accelerator Laboratory, Batavia, IL, United States of America28.
University of Chicago, Kavli Institute for Cosmological Physics, Chicago, IL, United States of America29.
Department of Physics and Astronomy, University of Sussex, Brighton, United Kingdom30.
Department of Physics, Northern Illinois University, DeKalb, IL, United States of America31.
Department of Physics and Astronomy, University of California, Irvine, CA, United States of America32.
Michigan State University, Dept. of Physics and Astronomy, East Lansing, MI, United States of America33.
Department of Physics, Royal Holloway, University of London, London, United Kingdom34.
INFN Sezione di Napoli, Complesso Universitario Monte Sant’Angelo, Napoli, Italy35.
Institut des Hautes Etudes Scientifiques, Bures-sur-Yvette, France36.
UNSAM - Universidad Nacional de San Martan, International Center for Advanced Studies (ICAS), Buenos Aires, Argentina37.
Northwestern University, Department of Physics and Astronomy, Evanston, IL, United States of America38.
University of Colorado at Boulder, Department of Physics, Boulder, CO, United States of America39.
Nikhef and University of Amsterdam, Amsterdam, The Netherlands40.
ETH Zurich, Institute for Particle Physics and Astrophysics, Zurich, Switzerland41.
University of Liverpool, Department of Physics, Liverpool, United Kingdom42.
Universit¨at Bonn, Physikalisches Institut, Bonn, Germany43.
University of Helsinki, Department of Physics, Helsinki, Finland44.
Budker Institute of Nuclear Physics SB RAS, Novosibirsk, Russian Federation45.
Novosibirsk State University, Novosibirsk, Russian Federation46.
King’s College London, Department of Physics, London, United Kingdom47.
Universidad Nacional Aut´onoma de M´exico, Departamento de F´ısica Te´orica, Instituto de F´ısica, M´exico, Mexico48.
University of Illinois, Department of Astronomy, Urbana, IL, United States of America49.
University of Illinois, Department of Physics, Urbana, IL, United States of America50.
Nuclear Science Division, Lawrence Berkeley National Laboratory, Berkeley, CA, United States of America51.
University of Hamburg, Hamburg, Germany52.
Deutsches Elektronen-Synchrotron DESY, Hamburg, Germany53.
University of Oxford, Denys Wilkinson Building, Department of Physics, Oxford, United Kingdom54.
University of Pittsburgh, Department of Physics and Astronomy, Pittsburgh, PA, United States of America55.
Tufts University, Department of Physics and Astronomy, Medford, MA, United States of America56.
CEA Saclay, DSM/IRFU/SPP, Gif-sur-Yvette, France57.
University of Warwick, Department of Physics, Coventry, United Kingdom58.
Department of Physics and Astronomy, Rutgers University, NJ, United States of America59.
University of Minnesota, School of Physics and Astronomy, Minneapolis, MN, United States of America60.
Argonne National Laboratory, Argonne, IL, United States of America61.
Johns Hopkins University, Baltimore, MD, United States of America62.
Theoriegruppe, Deutsches Elektronen-Synchrotron DESY, Hamburg, Germany63.
Institut f¨ur Physik, Humboldt-Universit¨at zu Berlin, Berlin, Germany64.
University College Dublin, School of Physics, Dublin, Ireland65.
Humanitas College, Kyung Hee University, Yongin, Kymgki 17104, Republic of Korea66.
Universit¨at T¨ubingen, Institut f¨ur Theoretische Physik, T¨ubingen, Germany67.
Santa Cruz Institute for Particle Physics, University of California, Santa Cruz, CA, United States of America68.
Institut f¨ur Kernphysik and Institute for Advanced Simulation, Forschungszentrum J¨ulich, J¨ulich, Germany69.
University of Tokyo, Department of Physics, Tokyo, Japan70.
Hillsdale College, Department of Physics, Hillsdale, MI, United States of America71.
Heidelberg University, Institute for Theoretical Physics, Heidelberg, Germany72.
Instituto de F´ısica Te´orica (UAM/CSIC), Universidad Aut´onoma de Madrid, Madrid, Spain73.
Campus of International Excellence UAM+CSIC, Universidad Aut`onoma de Madrid, Madrid, Spain74.
Instituto de F´ısica de Cantabria, CSIC-UC, Santander, Spain4
75.
Cornell University, Laboratory of Elementary-Particle Physics, Ithaca, NY, United States of America76.
Universitat de Val`encia — C.S.I.C., IFIC — Instituto de F´ısica Corpuscular, Valencia, Spain77.
University of Delaware, Department of Physics and Astronomy, Newark, DE, United States of America78.
University of Delaware, Bartol Research Institute, Newark, DE, United States of America79.
Kyoto University, Yukawa Institute for Theoretical Physics, Kyoto, Japan80.
Stanford University, Department of Physics, Stanford, CA, United States of America81.
SLAC National Accelerator Laboratory, Menlo Park, CA, United States of America82.
Florida State University, Department of Physics, Tallahassee, FL, United States of America83.
LAL, IN2P3-CNRS et Universit´es de Paris, Orsay CEDEX, France84.
Department of Particle Physics, Tel-Aviv University, Tel Aviv, Israel85.
Friedrich-Alexander University of Erlangen-N¨urnberg, Erlangen Centre for Astroparticle Physics, Erlangen, Germany86.
Universit¨at Bonn, Helmholtz-Institut f¨ur Strahlen- und Kernphysik, Bonn, Germany87.
University of Victoria, Victoria, BC, Canada88.
University of Durham, Institute for Particle Physics Phenomenology, Department of Physics, Durham, United Kingdom89.
University of Basel, Institute of Physics, Basel, Switzerland90.
Yonsei University, Department of Physics, Seoul, Republic of Korea91.
University College London, Department of Physics and Astronomy, London, United Kingdom92.
Syracuse University, Department of Physics, Syracuse, NY, United States of America93.
Institute of Theoretical Particle Physics and Cosmology (TTK), RWTH, Aachen, Germany94.
University of Edinburgh, Royal Observatory, Institute for Astronomy, Edinburgh, United Kingdom95.
GSI, Helmholtzzentrum f¨ur Schwerionenforschung, Darmstadt, Germany96.
Division of Science, City College of New York, New York, NY, United States of America97.
Scuola Normale Superiore, Pisa, Italy98.
INFN Sezione di Pisa, Pisa, Italy99.
Universit`e catholique de Louvain, Centre for Cosmology, Particle Physics and Phenomenology (CP3), Louvain-la-Neuve, Belgium100.
Universit¨at Siegen, Department f¨ur Physik, Siegen, Germany101.
Department of Physics, University of California at San Diego, La Jolla, CA, United States of America102.
INFN Sezione di Cagliari, Cittadella Universitaria di Monserrato, Monserrato, Italy103.
Louisana State University, Department of Physics and Astronomy, Baton Rouge, LA, United States of America104.
Stockholms Universitet, AlbaNova University Centre, Fysikum, Stockholm, Sweden105.
Indiana University, Department of Physics, Bloomington, IN, United States of America106.
DESY, Zeuthen, Germany107.
INAF-OATS, Trieste, Italy108.
University of Ghent, Dept. of Physics and Astronomy, Ghent, Belgium109.
University of California, Department of Physics, Berkeley, CA, United States of America110.
Brown University, Department of Physics, Providence, RI, United States of America111.
INFN Sezione di Milano-Bicocca, Piazza della Scienza, Milano, Italy112.
Universidad de Granada, Dpto. de F´ısica Te´orica y del Cosmos & C.A.F.P.E., Granada, Spain113.
Johannes Gutenberg University, PRISMA Cluster of Excellence and Mainz Institute for Theoretical Physics, Mainz, Germany114.
Department of Particle Physics and Astrophysics, Weizmann Institute of Science, Rehovot, Israel115.
Columbia University, Department of Physics, New York, NY, United States of America116.
Universit`a di Bologna and INFN, Dip. Scienze per la Qualit`a della Vita, Rimini, Italy117.
SISSA/INFN, Trieste, Italy118.
INRNE, Bulgarian Academy of Sciences, Sofia, Bulgaria119.
University of Alabama, Department of Physics and Astronomy, Tuscaloosa, AL, United States of America120.
Universitat Aut`onoma de Barcelona, Departament de F´ısica, Barcelona, Spain121.
IFAE, Universitat Aut`onoma de Barcelona, Barcelona, Spain122.
Georg-August-Universit¨at G¨ottingen, II. Physikalisches Institut, G¨ottingen, Germany123.
University of Bristol, HH Wills Physics Laboratory, Bristol, United Kingdom124.
Max-Planck-Institut f¨ur Physik (Werner-Heisenberg-Institut), M¨unchen, Germany125.
DOE, Washington, DC, United States of America126.
National Research Nuclear University ”MEPhI”, Moscow, Russian Federation127.
University of Southampton, School of Physics and Astronomy, Southampton, United Kingdom128.
LPTHE, UPMC Universit´e de Paris 6, Paris, France5
129.
University of Oxford, Rudolf Peierls Centre for Theoretical Physics, Oxford, United Kingdom130.
Niels Bohr Institute, Copenhagen, Denmark131.
Institute of Physics, Ecole Polytechnique F´ed´erale de Lausanne (EPFL), Lausanne, Switzerland132.
Duke University, Physics Department, Durham, NC, United States of America133.
University of Cincinnati, Department of Physics, Cincinnati, OH, United States of America134.
University of British Columbia, Department of Physics and Astronomy, Vancouver, BC, Canada135.
Lund University, Department of Astronomy and Theoretical Physics, Lund, Sweden136.
Monash University, School of Physics, Melbourne, Australia137.
Paris Centre for Cosmological Physics, APC (CNRS), Universit´e Paris Diderot, Universit´e Sorbonne Paris Cit´e, Paris, France138.
University of Tennessee, Department of Physics and Astronomy, Knoxville, TN, United States of America139.
III. Physikalisches Institut, Physikzentrum, RWTH Aachen University, Aachen, Germany140.
High Energy Physics Laboratory, Tokyo Metropolitan University, Tokyo, Japan141.
Department of Physics, University of California, Davis, CA, United States of America142.
Institut f¨ur Kernphysik, Johannes Gutenberg University, Mainz, Germany143.
University of Sheffield, Department of Physics and Astronomy, Sheffield, United Kingdom144.
University of Illinois at Chicago, Chicago, IL, United States of America145.
Instituto de ciencias del Cosmos (ICC), University of Barcelona, Barcelona, Spain146.
Instituci´o Catalana de Recerca i Estudis Avancats, Barcelona, Spain147.
Carleton University, Department of Physics, Ottawa, ON, Canada148.
California Institute of Technology, Kellogg Radiation Laboratory, Pasadena, CA, United States of America149.
The University of Liverpool, Division of Theoretical Physics, Department of Mathematical Sciences, Liverpool, United Kingdom150.
University of Portsmouth, Institute of Cosmology and Gravitation, Portsmouth, United Kingdom151.
Cavendish Laboratory, Cambridge, United Kingdom152.
Ohio State University, Department of Astronomy and CCAPP, Columbus, OH, United States of America153.
Dept. of Physics, Colorado School of Mines, Golden, CO, United States of America154.
University of Massachusetts, Department of Physics, Amherst, MA, United States of America155.
STFC Rutherford Appleton Laboratory, Didcot, United Kingdom156.
George Washington University Virginia Campus, Department of Physics, Ashburn, VA, United States of America157.
Moscow Institute of Physics and Technology, Dolgoprudny, Russian Federation158.
California Institute of Technology, High Energy Physics, Pasadena, CA, United States of America159.
School of Physics, Peking University, Beijing, China6 Highlights of the 2018 edition of the Review of Particle Physics
HIGHLIGHTS OF THE 2018 EDITION OF THE REVIEW OF PARTICLE PHYSICS
758 new papers with 2873 new measurements
• Over 367 new papers from LHC experiments (ATLAS, CMS, and LHCb).
• Extensive up-to-date Higgs boson coverage from 56 new papers with 99 measurements;
provides latest results on mass, couplings, de- cay width, and branching ratios, plus searches for other neutral and charged Higgs bosons.
• Supersymmetry: 90 new papers with major exclusions.
• Top quark: 54 new papers.
• Latest from B-meson physics: 112 papers with 405 measurements, including some hints of possible deviations from SM predictions related to lepton flavor non-universality.
• Improved naming scheme for charmonium and bottomonium states (commonly referred to as X, Y or Z states).
• Many new results to and improvements in unstable meson Listings.
• Six new charmed baryons (24 in total), fitting nicely into SU(4) multiplets.
• Substantial updates to N and ∆ resonances Summary Tables.
• New limits on neutrinoless double-β decays;
two-neutrino mode measurements and neutri- noless mode limits now listed separately.
• Periodic Table with complete 7th row and newly approved names (nihonium, moscovium, tennessine, oganesson).
See pdgLive.lbl.gov for online access to PDG data.
See pdg.lbl.gov/AtomicNuclearProperties for Atomic and Nuclear Properties of Materials.
118 reviews (most are revised)
• New review on Neutrinos in Cosmology.
• Significant update/revision to reviews on:
- Status of Higgs Boson Physics sum- marizes latest results and discusses non-standard models of Higgs bosons.
- Supersymmetry (Theory and Ex- periment) interprets latest results in simplified models with various assump- tions.
- Axions summarizes recent searches, discusses axion as dark matter.
- CKM Quark-Mixing Matrix presents latest fits to mixing matrix.
- Electroweak Model provides compre- hensive fit using many inputs; discusses implications of electroweak fits for con- straints on new physics.
- Experimental Tests of Gravita- tional Theory with LIGO-VIRGO observation of gravitational waves.
- Neutrino Masses, Mixing, and Oscillations discusses latest results from solar, atmospheric, reactor, and accelerator-based neutrino experiments.
- Accelerator Physics has latest ten- tative parameters of selected future colliders; High-Energy Collider Pa- rameters gives parameters for run- ning/approved colliders.
- Discussion of Generative Adversarial
Networks (GANs) added to Monte-
Carlo Techniques.
Table of contents 7
VOLUME 1: SUMMARY TABLES AND REVIEWS
Highlights 6
Introduction 11
History plots 20
Online particle physics information 21 SUMMARY TABLES
Gauge and Higgs bosons 33
Leptons 36
Quarks 40
Mesons 41
Meson quick reference table 92
Baryon quick reference table 93
Baryons 94
Searches not in Other Sections 111
Tests of conservation laws 113
REVIEWS, TABLES, AND PLOTS
Constants, Units, Atomic and Nuclear Properties
1. Physical constants (rev.) 127
2. Astrophysical constants (rev.) 128 3. International system of units (SI) 130 4. Periodic table of the elements (rev.) 131 5. Electronic structure of the elements 132 6. Atomic and nuclear properties of materials (rev.) 134
7. Electromagnetic relations 136
8. Naming scheme for hadrons (rev.) 138 Standard Model and Related Topics
9. Quantum chromodynamics (rev.) 141
10. Electroweak model and 161
constraints on new physics (rev.)
11. Higgs boson physics, status of (rev.) 180 12. CKM quark-mixing matrix (rev.) 229 13. CP violation in the quark sector (rev.) 238 14. Neutrino mass, mixing, and oscillations (rev.) 251
15. Quark model (rev.) 287
16. Heavy-quark & soft-collinear effective 299 theory (rev.)
17. Lattice quantum chromodynamics (rev.) 306
18. Structure functions (rev.) 318
19. Fragmentation functions in e
+e
−, ep 334 and pp collisions (rev.)
Astrophysics and Cosmology
20. Experimental tests of gravitational theory (rev.) 346
21. Big-Bang cosmology (rev.) 352
22. Inflation (rev.) 364
23. Big-Bang nucleosynthesis (rev.) 377 24. Cosmological parameters (rev.) 383 25. Neutrinos in cosmology (new) 390
26. Dark matter (rev.) 396
27. Dark energy (rev.) 406
28. Cosmic microwave background (rev.) 414
29. Cosmic rays (rev.) 424
Experimental Methods and Colliders
30. Accelerator physics of colliders (rev.) 433 31. High-energy collider parameters (rev.) 440 32. Neutrino beam lines at high-energy 445
proton synchrotrons (rev.)
33. Passage of particles through matter 446 34. Particle detectors at accelerators (rev.) 461 35. Particle detectors for non-accelerator phys. (rev.) 496 36. Radioactivity and radiation protection (rev.) 515 37. Commonly used radioactive sources (rev.) 521 Mathematical Tools
38. Probability 522
39. Statistics (rev.) 527
40. Monte Carlo techniques (rev.) 542 41. Monte Carlo event generators (rev.) 546 42. Monte Carlo neutrino event generators (rev.) 557 43. Monte Carlo particle numbering scheme (rev.) 560 44. Clebsch-Gordan coefficients, spherical 564
harmonics, and d functions
45. SU(3) isoscalar factors and representation 565 matrices
46. SU(n) multiplets and Young diagrams 566 Kinematics, Cross-Section Formulae, and Plots
47. Kinematics (rev.) 567
48. Resonances (rev.) 571
49. Cross-section formulae for specific processes 576 50. Neutrino cross section measurements (rev.) 585 51. Plots of cross sections and related 590
quantities (rev.) Particle Properties
Gauge Bosons
52. Mass and width of the W boson (rev.) 604
53. Extraction of triple 606
gauge couplings (TGC’s) (rev.)
54. Anomalous W/Z quartic couplings (rev.) 607
55. Z boson (rev.) 608
56. Anomalous ZZγ, Zγγ, and ZZV couplings 613 Leptons
57. Muon anomalous magnetic moment (rev.) 614
58. Muon decay parameters 617
59. τ branching fractions (rev.) 620
60. τ -lepton decay parameters 623
61. Number of light neutrino types 625 from collider experiments
62. Neutrinoless double-β decay (rev.) 626
63. Neutrino properties 628
64. Sum of neutrino masses (rev.) 629 65. Three-neutrino mixing parameters (rev.) 630 Quarks
66. Quark masses (rev.) 631
67. Top quark (rev.) 638
(Continued on next page.)
8 Table of contents
Mesons
68. Form factors for radiative 656
pion & kaon decays (rev.)
69. Scalar mesons below 2 GeV (rev.) 658
70. ρ(770) 664
71. Pseudoscalar and pseudovector mesons 665 in the 1400 MeV region (rev.)
72. ρ(1450) and the ρ(1700) (rev.) 667
73. Charged kaon mass 669
74. Rare kaon decays (rev.) 671
75. Dalitz plot parameters for K → 3π decays 675 76. K
ℓ3±and K
ℓ30form factors 676 77. CP T invariance tests in neutral kaon decay 678
78. CP -violation in K
S→ 3π 680
79. V
ud, V
us, Cabibbo angle, 681 and CKM unitarity (rev.)
80. CP -violation in K
Ldecays 684 81. Review of multibody charm analyses (rev.) 688
82. D
0–D
0mixing (rev.) 691
83. D
+sbranching fractions 698
84. Leptonic decays of charged pseudoscalar mesons 700 85. Production and decay of b-flavored hadrons (rev.) 711 86. Heavy Flavor Averaging Group (rev.) 721 87. Polarization in B decays (rev.) 722
88. B
0–B
0mixing (rev.) 725
89. Semileptonic B decays, V
cband V
ub(rev.) 731 90. Spectroscopy of mesons containing 743
two heavy quarks (rev.)
91. Charmonium system 749
92. Branching ratios of ψ(2S) and χ
c0,1,2(rev.) 750
93. Bottomonium system 751
94. Width determination of the Υ states 752
95. Non-qq mesons (rev.) 753
Baryons
96. Baryon decay parameters 758
97. N and ∆ resonances (rev.) 759
98. Baryon magnetic moments 763
99. Λ and Σ resonances 764
100. Pole structure of the Λ(1405) region 766
101. Σ(1670) region 767
102. Radiative hyperon decays 768
103. Ξ resonances 769
104. Charmed baryons (rev.) 770
105. Pentaquarks 772
Hypothetical Particles and Concepts
106. Extra dimensions (rev.) 776
107. W
′-boson searches (rev.) 783
108. Z
′-boson searches (rev.) 786
109. Supersymmetry: theory (rev.) 790 110. Supersymmetry: experiment (rev.) 807 111. Axions and other similar particles (rev.) 821 112. Quark and lepton compositeness, 831
searches for (rev.)
113. Dynamical electroweak symmetry breaking: 837 implications of the H(0) (rev.)
114. Grand unified theories (rev.) 847
115. Leptoquarks (rev.) 861
116. Magnetic monopoles (rev.) 863
INDEX (Volume 1) 869
VOLUME 2: PARTICLE LISTINGS (available online only)
Illustrative key and abbreviations
Illustrative key 885
Abbreviations 886
Gauge and Higgs bosons
(γ, gluon, graviton, W , Z, Higgs, Axions) 897 Leptons
(e, µ, τ, Heavy-charged lepton searches, 973 Neutrino properties, Number of neutrino types Double-β decay, Neutrino mixing,
Heavy-neutral lepton searches) Quarks
(u, d, s, c, b, t, b
′, t
′(4
thgen.), Free quarks) 1037 Mesons
Light unflavored (π, ρ, a, b) (η, ω, f , φ, h) 1069
Other light unflavored 1183
Strange (K, K
∗) 1188
Charmed (D, D
∗) 1236
Charmed, strange (D
s, D
∗s, D
sJ) 1291 Bottom (B, V
cb/V
ub, B
∗, B
∗J
) 1308
Bottom, strange (B
s, B
∗s
, B
∗sJ
) 1473
Bottom, charmed (B
c) 1495
cc (η
c, J/ψ(1S), χ
c, h
c, ψ) 1498
bb (η
b, Υ, χ
b, h
b) 1605
Baryons
N 1643
∆ 1693
Λ 1716
Σ 1738
Ξ 1769
Ω 1780
Charmed (Λ
c, Σ
c, Ξ
c, Ω
c) 1783
Doubly charmed (Ξ
cc) 1805
Bottom (Λ
b, Σ
b, Ξ
b, Ω
b, b-baryon admixture) 1806 Exotic baryons (P
cpentaquarks) 1819 Searches not in Other Sections
Magnetic monopole searches 1823
Supersymmetric particle searches 1825
Technicolor 1857
Searches for quark and lepton compositeness 1858
Extra dimensions 1862
WIMP and dark matter searches 1867
Other particle searches 1875
INDEX (Volumes 1 and 2 combined) 1883
INTRODUCTION
1. Overview . . . . 11
2. Particle Listings responsibilities . . . . 11
3. Consultants . . . . 12
4. Naming scheme for hadrons . . . . 15
5. Procedures . . . . 15
5.1 Selection and treatment of data . . . . 15
5.2 Averages and fits . . . . 16
5.2.1 Treatment of errors . . . . 16
5.2.2 Unconstrained averaging . . . . 16
5.2.3 Constrained fits . . . . 17
5.3 Rounding . . . . 18
5.4 Discussion . . . . 18
History plots . . . . 20
ONLINE PARTICLE PHYSICS INFORMATION 1. Introduction . . . . 21
2. Particle Data Group (PDG) resources . . . . 21
3. Particle physics information platforms . . . . 21
4. Literature databases . . . . 22
5. Particle physics journals and conference proceedings series . . . 22
6. Conference databases . . . . 22
7. Research institutions . . . . 23
8. People . . . . 23
9. Experiments . . . . 23
10. Jobs . . . . 23
11. Software repositories . . . . 23
12. Data repositories . . . . 24
13. Data preservation . . . . 25
14. Particle physics education and outreach sites . . . . 26
Introduction 11
INTRODUCTION
1. Overview
The Review of Particle Physics is a comprehensive review of the field of Particle Physics and of related areas in Cosmology. It consists of “Summary Tables”, “Reviews, Tables, and Plots”, and “Particle Listings”. Starting with this edition, the Review is divided into two volumes. Volume 1 includes the Summary Tables and Reviews, Tables, and Plots with all review articles. Volume 2 consists of the Particle Listings. Review articles that were previously part of the Listings are now included in Reviews, Tables and Plots in volume 1.
The contents of the Review are updated and made available on the PDG website (http://pdg.lbl.gov) each year. In even-numbered years, the Review is published in a journal and made available in print as the PDG Book together with an abridged Particle Physics Booklet containing Summary Tables and essential tables, figures, and equations from selected review articles. This edition is an updating through January 2018.
The Summary Tables give our best values and limits for particle properties such as masses, widths or lifetimes, and branching fractions, as well as an extensive summary of searches for hypothetical particles and a summary of experimental tests of conservation laws.
The 116 review articles in Reviews, Tables and Plots cover a wide variety of theoretical and experimental topics.
Together with the Summary Tables they provide a quick reference for the practicing particle physicist. Two more review articles, Online Particle Physics Information and Tests of Conservation Laws, can be found in the Introduction and Summary Tables, respectively.
The Particle Listings are a compilation/evaluation of data on particle properties. They contain all the data used to get the values given in the Summary Tables. They also give information on unconfirmed particles and particle searches.
In this edition, the Particle Listings include 2,873 new measurements from 758 papers, in addition to the 38,498 measurements from 10,564 papers that first appeared in previous editions [1]. Because of the large quantity of data, the Particle Listings are not an archive of all published data on particle properties. We refer interested readers to earlier editions for data now considered to be obsolete.
We organize the particles into six categories:
Gauge and Higgs bosons Leptons
Quarks Mesons Baryons
Searches not in other sections
The last category only includes searches for particles that do not belong to the previous groups. For example, it includes searches for supersymmetric particles, compositeness and extra dimensions, while searches for heavy charged leptons and massive neutrinos are with the leptons.
In Sec. 2 of this Introduction, we list the main areas of responsibility of the authors of the Particle Listings. Our many consultants, without whom we would not have been able to produce this Review, are acknowledged in Sec. 3. In Sec. 4, we mention briefly the naming scheme for hadrons, which has been extended in this edition. In Sec. 5, we discuss
our procedures for choosing among measurements of particle properties and for obtaining best values of the properties from the measurements.
The accuracy and usefulness of this Review depend in large part on interaction between its users and the authors.
We appreciate comments, criticisms, and suggestions for improvements of any kind. Please send them to the appropriate author, according to the list of responsibilities in Sec. 2 below, or to pdg@lbl.gov.
In addition to the online publication, the Review is available in different formats:
• The printed PDG Book includes volume 1 only, i.e. it contains the Summary Tables and all review articles.
Since the 2016 edition the detailed tables from the Particle Listings are no longer printed.
• The Particle Physics Booklet includes the Summary Tables plus essential tables, figures, and equations from selected review articles. Compared to recent Booklets, we have excluded most text and explanations in order to revert back to a more pocket-sized format.
• pdgLive (http://pdgLive.lbl.gov) is a web application giving more interactive access to PDG data than the static web pages and PDF files that are also available.
• Files that can be downloaded from the PDG website include a table of masses, widths, and PDG Monte Carlo particle ID numbers; PDF files of volume 1 (PDG Book), volume 2 (Particle Listings) and Booklet; individual review articles; all figures; and an archive file containing the complete PDG website (except for pdgLive).
Copies of the PDG Book or the Particle Physics Booklet can be ordered from our website or directly at http://pdg.lbl.gov/order. For special requests only, please email pdg@lbl.gov in North and South America, Australia, and the Far East, and pdg-products@cern.ch in all other areas.
This Review is considered to be a single comprehensive review of particle physics and related areas. Therefore we prefer that it be cited as a whole, rather than citing e.g. an individual review article that is part of this Review. For the 2018 edition, the proper citation is:
M. Tanabashi et al. (Particle Data Group), Phys. Rev.
D 98, 030001 (2018)
If you wish to refer to a specific part of the Review, for example to the Higgs boson review article, the following form should be used:
Status of Higgs Boson Physics in M. Tanabashi et al.
(Particle Data Group), Phys. Rev. D 98, 030001 (2018)
2. Particle Listings responsibilities
* Asterisk indicates the people to contact with questions or comments about Particle Listings sections.
Gauge and Higgs bosons
γ A. Bettini, D.E. Groom
∗Gluons R.M. Barnett,
∗A.V. Manohar Graviton A. Bettini
∗, D.E. Groom W, Z A. Gurtu,
∗M. Gr¨ unewald
∗Higgs bosons S. Heinemeyer,
∗K. Hikasa, J. Tanaka
Heavy bosons R.M. Barnett,
∗M. Tanabashi
Axions K.A. Olive, G. Raffelt,
∗F. Takahashi
12 Introduction
Leptons
Neutrinos M. Goodman, C.-J. Lin,
∗K. Nakamura, K.A. Olive, A. Piepke, P. Vogel e, µ C. Grab, A. Bettini
∗τ A. Lusiani, K. M¨onig
∗Quarks
Quarks R.M. Barnett,
∗A.V. Manohar Top quark R.M. Barnett,
∗Y. Sumino b
′, t
′R.M. Barnett,
∗Y. Sumino Free quark A. Bettini,
∗C.-J. Lin Mesons
π, η A. Bettini,
∗C. Grab
Unstable mesons C. Amsler, M. Doser,
∗S. Eidelman,
∗T. Gutsche, C. Hanhart, B. Heltsley, J. J. Hern´andez-Rey, A. Masoni, R.E. Mitchell, S. Navas, C. Patrignani, S. Spanier, G. Venanzoni
K (stable) G. D’Ambrosio, C.-J. Lin
∗D (stable, no mix.) J. Rademacker, C.G. Wohl
∗D
0mixing D.M. Asner, W.-M. Yao
∗B (stable) A. Cerri,
∗P. Eerola, M. Kreps,
Y. Kwon, W.-M. Yao
∗Baryons
Stable baryons C. Grab, C.G. Wohl
∗Unstable baryons V. Burkert, E. Klempt, U. Thoma, L. Tiator, R.L. Workman
∗Charmed baryons J. Rademacker, C.G. Wohl
∗Bottom baryons A. Cerri,
∗P. Eerola, M. Kreps,
Y. Kwon, W.-M. Yao
∗Miscellaneous searches
Monopole A. Bettini,
∗D. Milstead Supersymmetry M. D’Onofrio, H.K. Dreiner,
∗A. de Gouvˆea, F. Moortgat, K.A. Olive
Technicolor K. Agashe,
∗M. Tanabashi Compositeness M. Tanabashi, J. Terning
∗Extra Dimensions D.A. Dwyer,
∗T. Gherghetta, K.A. Olive WIMP, DM, Other A. Bettini,
∗, H. Baer, K.A. Olive,
W.-M. Yao,
∗3. Consultants
The Particle Data Group benefits greatly from the assistance of hundreds of physicists who are asked to verify every piece of data entered into this Review. Of special value is the advice of the PDG Advisory Committee which meets biennially and thoroughly reviews all aspects of our operation. The members of the 2018 committee are:
T. Carli (CERN)
L. Hall (UC Berkeley/LBNL) T. Nakada (EPFL)
A. Seiden (UCSC) A. Slosar (BNL) M. Yokoyama (Tokyo) Q. Zhao (IHEP Beijing)
We have especially relied on the expertise of the following people for advice on particular topics:
• M. Achasov (Budker Inst., Novosibirsk)
• W. Adam (Austrian Academy of Sciences)
• E.G. Adelberger (FNAL)
• D.S. Akerib (SLAC)
• J. Alcaraz (CERN)
• A. Ali (DESY, Hamburg)
• B. Allanach (DAMPT, Cambridge U.)
• D. Amidei (Michigan U.)
• B. Ananthanarayan (IISC)
• V. Anisovich (Petersburg Nuclear Phys. Inst.)
• A. Antognini (ETH Zurich)
• F. Anulli (INFN, Rome)
• E. Aprile (Columbia U.)
• G. Arduini (CERN)
• E. Armengaud (CEA Saclay, DSM/IRFU/SPP)
• M. Artuso (Syracuse U.)
• N. Ayres (Sussex U.)
• H. Bachacou (IRFU, Saclay)
• M. Bales (Munchen Tech. U.)
• M. Bardeen (FNAL)
• J. Barranco (Guanajuato U.)
• B. Batell (Pittsburg U.)
• L. Baudis (Z¨ urich U.)
• O. Behnke (DESY, Hamburg)
• R. Bernabei (Rome U. Tor Vergata)
• F. Bernlochner (Karlsruhe U.)
• W. Bertl (PSI)
• V. Bertone (NIKHEF)
• M. Bettler (CERN)
• S. Borghi (Manchester U.)
• D. Boscherini (INFN, Bologna)
• T. Bose (Boston U.)
• E. Braaten (Ohio State U.)
• A. Branca (INFN, Padova)
• R.A. Briere (Carnegie Mellon U.)
• T. Browder (Hawaii U.)
• B.M. Brubaker (Art Inst. of Chicago)
• P. Brun (DAPNIA, Saclay)
• R. Budnik (Weizmann Inst.)
• A. Cabrera (APC, Paris)
• W. Cairncross (Colorado U., Boulder)
• A. Canto (CERN)
• J. Cao (IHEP Beijing)
• R. Caputo (UC Santa Cruz)
• T. Carli (CERN)
• F. Cei (Pisa U.)
• F. Cerutti (LBNL)
• A. Chao (SLAC)
• K. Chetyrkin (KIT)
• G. Chiarelli (INFN, Pisa)
• J. Chou (Rutgers U.)
• X. Cid Vidal (Santiago de Compostela U.)
• D. Cinabro (Wayne State U.)
• M. Cirelli (LPTHE, Paris)
• G. Colangelo (Bern U.)
• J. Collar (Chicago U.)
• J. Conrad (Stockholm U.)
• A. Contu (INFN, Cagliary)
• A. Corsico (La Plata U.)
• K. Cranmer (NYU)
• O. Cremonesi (INFN, Milano-Bicocca)
Introduction 13
• P.B. Cushman (Minnesota U.)
• I. Danilkin (KPH, JGU Mainz)
• C. Davies (Glasgow U.)
• A.N. Davis (Tsinghua U.)
• B. Dawson (Adelaide U.)
• J. Delahaye (CERN)
• G. de Lellis (INFN, Napoli)
• F. Della Valle (Trieste U.)
• D. Denisov (FNAL)
• D. d’Enterria (CERN)
• S. Derenzo (LBNL)
• G. DeRijk (CERN)
• U. De Sanctis (Rome U. Tor Vergata)
• S. Descotes-Genon (Paris-Sud U.)
• U. Dey (Indian Inst. Tech., Kharagpur)
• M. Diamond (Toronto U.)
• J. Donini (Clermont-Ferrand U.)
• F. Dordei (CERN)
• T. Dorigo (INFN, Padova)
• V.P. Druzhinin (Budker Inst., Novosibirsk)
• A. Dubnickova (Comenius U.)
• A. Dzyuba (Petersburg Nuclear Phys. Inst.)
• G. Edda (CERN)
• U. Egede (Imperial Coll. London)
• T. Eifert (CERN)
• G. Eigen (Bergen U.)
• S.R. Elliott (LANL)
• R.K. Ellis (FNAL)
• E. Elsen (CERN)
• C. Enss (Heidelberg U.)
• R. Essig (YITP, Stony Brook)
• G. Facini (London U.)
• A. Ferrari (CERN)
• F. Ficek (UJ, Krakow)
• L.J. Fields (FNAL)
• W. Fischer (BNL)
• V. Flambaum (New South Wales U.)
• Z. Fodor (Wuppertal U.)
• M. Fornasa (INFN, Padova)
• K. Freese (Michigan U.; Nordita, Stockholm)
• B. Fujikawa (NSD LBNL)
• P. Gambino (INFN, Torino)
• J. Gao (IHEP Beijing)
• R. Garisto (APS)
• M. Genest (CNRS)
• E. Gersabeck (Heidelberg U.)
• S. Giovannella (INFN, Frascati)
• E. Giusarma (LBNL)
• C. Glasman (U. Aut`onoma de Madrid)
• A. Glazov (DESY, Hamburg)
• N. Glover (Durham U.)
• S.N. Gninenko (Russian Academy of Sciences)
• C. Gobel Burlamaqui de Mello (PUC-Rio)
• T. Golan (WrocÃlaw U.)
• T. Golling (Geneva U.)
• G. Gonzalez (Louisiana State U.)
• R. Gonzalez Suarez (Nebraska U.)
• E. Goudzovski (Birmingham U.)
• P. Grabmayr (T¨ ubingen U.)
• B. Graner (Washington U.)
• G. Gratta (Stanford U.)
• H. Haberzettl (Georg Washington U.)
• J. Haidenbauer (Forschungszentrum J¨ ulich)
• F. Halzen (Wisconsin U.)
• S. Hannestad (Aarhus U.)
• D.A. Harris (FNAL)
• F.A. Harris (Hawaii U.)
• A. Hasenfratz (Colorado U., Boulder)
• U. Heintz (Brown U.)
• R. Henning (North Carolina U.)
• A. Hinzmann (Hamburg U.)
• A. Hoang (HEPHY, Vienna)
• D. Holz (Chicago U., Kavli Inst.)
• J. Horandel (Radboud U.)
• Q. Huang (Beijing Inst. Theor. Phys.)
• X. Huang (Niels Bohr Inst.)
• A. Ianni (Gran Sasso)
• P. Ilten (Birmingham U.)
• T. Inada (Tokyo U.)
• K. Inoue (Tohoku U.)
• I.G. Irastorza (U. de Zaragoza)
• J. Jaeckel (Heidelberg U.)
• F. Jegerlehner (Physik, Humboldt U.)
• X. Ji (Maryland U.)
• D. Johnson (CERN)
• C. Joram (CERN)
• J. Jowett (CERN)
• K. Kaadze (CERN)
• M. Kagan (SLAC)
• F. Kahlhoefer (DESY, Hamburg)
• J. Kaminski (Bonn U.)
• K. Kampert (Wuppertal U.)
• D. Karlen (Victoria U.)
• T. Katori (Queen Mary U. of London)
• V. Kekelidze (JINR, Dubna)
• M. Kenzie (Cambridge U.)
• S. Kettell (BNL)
• J.E. Kim (Seoul National U.)
• S. Kim (Seoul National U.)
• M. Klein (Liverpool U.)
• B. Ko (IBS, Daejeon)
• R. Kogler (Hamburg U.)
• K. Kohri (KEK)
• P.S. Koppenburg (NIKHEF)
• T. Koseki (KEK)
• A. Kouchner (Paris 7)
• W. Kozanecki (U. Paris-Saclay)
• D. Kreinick (Cornell U.)
• A. Kronfeld (FNAL)
• G. Kumar (PRL, Ahmedabad)
• C.M. Kuo (NCU)
• A. Kupsc (Uppsala U.)
• G. Lambard (IFIC, Valencia)
• G. Landsberg (Brown U.)
• H. Lee (BNL)
• N. Leite (Hamburg U.)
• G.P. Lepage (Cornell U.)
• O. Leroy (CPPM Marseille)
• H. Li (IHEP Beijing)
• Z. Li (IHEP Beijing)
• J. Libby (Indian Inst. Tech., Madras)
• J. Liu (SJTU)
14 Introduction
• D. London (U. de Montreal)
• Y. Lu (IHEP Beijing)
• P. Luo (Huazhong U. of Science and Technology)
• N. Lurkin (Birmingham U.)
• X. Lyu (UCAS, Beijing)
• Y. Maeda (Kyoto U.)
• K. Mahn (Michigan State U.)
• L. Maisenbacher (MPQ, Garching)
• B. Malaescu (CNRS)
• G. Mandaglio (Messina U.)
• B. Mansoulie (CEA Saclay, DSM/IRFU/SPP)
• M. Marsh (DAMPT, Cambridge U.)
• S.P. Martin (Northern Illinois U.)
• M. Martinelli (CERN)
• R. Maruyama (Yale U.)
• A. Melchiorri (Rome U.)
• P. Meridiani (INFN, Rome)
• P. Mermod (Geneva U.)
• M. Messier (Indiana U.)
• I. Mikulec (Austrian Academy of Sciences)
• S. Mine (UC Irvine)
• S.R. Mishra (South Carolina U.)
• M. Misiak (Warsaw U.)
• S. Moch (Hamburg U.)
• N.V. Mokhov (FNAL)
• S. Moretti (Southampton U.)
• V.M. Mostepanenko (Pulkovo Obs., St.Petersburg)
• M. Moulson (INFN, Frascati)
• B. Murray (Warwick U.)
• H. Nagahama (Tokyo U.)
• S. Nagaitsev (FNAL)
• T. Nakadaira (KEK)
• M. Nakahata (Kamioka Observ.)
• T. Nakaya (Kyoto U.)
• T. Namikawa (Stanford U.)
• S. Narison (Montpellier U.)
• S. Neubert (Ruprecht Karls U., Heidelberg)
• J.S. Nico (NIST)
• Y. Nomura (UC Berkley)
• J.A. Nowak (Lancaster U.)
• A. Nucciotti (INFN, Milano-Bicocca)
• D. Nygren (Texas U.)
• V. Obraztsov (IHEP, Protvino)
• W. Ochs (MPI Munich)
• H.B. O’Connell (Chicago U.)
• Y. Oh (IBS, Daejeon)
• J. Oller (Murcia U.)
• S.L. Olsen (Seoul National U.)
• R.A. Ong (UC Los Angeles)
• Y. Onishi (KEK)
• G. Orebi Gann (LBNL)
• A. Orso Maria Iorio (INFN, Napoli)
• P. Owen (Imperial Coll. London)
• N. Palanque-Delabrouille (Paris U.)
• S. Palestini (CERN)
• V.S. Pantuev (INR, Moscow)
• T. Papadopoulou (Athens U.)
• H. Park (IBS, Daejeon)
• S. Pastor (IFIC, Valencia)
• J.R. Pelaez (UCM, Madrid)
• S. Perazzini (CERN)
• A. Pich (IFIC, Valencia)
• M. Pieri (UC San Diego)
• A. Plante (U. de Montreal)
• R.K. Plunkett (FNAL)
• A. Pocar (Massachusetts U.)
• I. Polyakov (Syracuse U.)
• A. Poon (NSD LBNL)
• F. Porter (CALTECH)
• S. Prakhov (UC Los Angeles)
• F. Proebst (MPI Munich)
• W. Przygoda (UJ, Krakow)
• G. Pugliese (INFN, Bari)
• S. Rahatlou (UC San Diego)
• M. Redi (CERN)
• G. Ricciardi (INFN, Napoli)
• J.D. Richman (UC Santa Barbara)
• J. Rico (ICREA, Barcelona)
• T.G. Rizzo (SLAC)
• B.L. Roberts (Boston U.)
• J.M. Roney (Victoria U.)
• M. Rotondo (INFN, Frascati)
• B. Sadoulet (LBNL)
• B. Sahoo (PRL, Ahmedabad)
• A. Sakharov (NYU)
• G. Salam (LPTHE, Paris)
• R. Salerno (CNRS)
• V. Sanz (Sussex U.)
• A. Sarantsev (Bonn U.)
• X. Sarazin (LAL Orsay)
• E. Sarkisyan-Grinbaum (Texas U.)
• T. Sato (Osaka U.)
• M. Schmaltz (Boston U.)
• G. Schneider (Mainz U.)
• S. Schoenert (Munich Tech. U.)
• M. Schott (JGU, Mainz)
• D. Schulte (CERN)
• R.A. Schumacher (Carnegie Mellon U.)
• C. Schwanda (HEPHY, Vienna)
• R. Schwienhorst (Michigan State U.)
• S. Sellner (RIKEN)
• K.K. Seth (Northwestern U.)
• E. Shabalina (Georg August U. Goettingen)
• L. Shchutska (ETH Zurich)
• X. Shen (IHEP Beijing)
• Z. Shen (PMO, Nanjing)
• V. Shiltsev (FNAL)
• M. Shirasaki (NAOJ, Tokyo)
• Y. Shirman (UC Irvine)
• V. Shklyar (Giessen U.)
• P. Sikivie (Florida U.)
• P. Silva (CERN)
• A. Simone (INFN, Milano-Bicocca)
• A. Smirnov (ICTP)
• C. Smorra (RIKEN)
• D.P. Snowden-Ifft (OXY)
• J. Sobczyk (WrocÃlaw U.)
• E.P. Solodov (Budker Inst., Novosibirsk)
• A.D. Spallicci (Orleans U.)
• P. Spradlin (Glasgow U.)
• Y. Stadnik (New South Wales U.)
• M. Strovink (UC Berkley)
Introduction 15
• O.V. Suvorova (INR, Moscow)
• A. Svarc (Ruder Boˇskovi´c I..)
• K. Tackmann (DESY, Hamburg)
• A. Tapper (Imperial Coll. London)
• X. Tata (Hawaii U.)
• R. Tenchini (INFN, Pisa)
• R. Tesarek (FNAL)
• T. Teubner (Liverpool U.)
• J. Thomas (NSD LBNL)
• P. Tiwari (Beijing Observ.)
• K. Trabelsi (KEK)
• M. Trassinelli (LPTHE, Paris)
• R.D. Tripp (LBNL)
• Y. Uchiyama (Tokyo U.)
• S. Ulmer (RIKEN)
• A. Uras (IPN, Lyon)
• P. Urquijo (School of Phys. U. of Melbourne)
• V. Vagnoni (INFN, Bologna)
• K.A. van Bibber (UC Berkley)
• C. van Eldik (Erlangen U.)
• R. Van Kooten (Indiana U.)
• Y.W. Wah (Chicago U.)
• J. Walder (Lancaster U.)
• D. Wang (IHEP Beijing)
• B. Webber (Cambridge U.)
• W. Weise (Munich Tech. U.)
• M.R. Whalley (Durham U.)
• M. Whitehead (RWTH Aachen)
• M. Wing (University Coll. London)
• E. Won (Korea U.)
• B.D. Yabsley (Sydney U.)
• A. Yamamoto (KEK)
• T. Yamanaka (Osaka U.)
• T. Yanagida (Kavli IPMU (WPI), U. Tokyo)
• L. Yang (Illinois U.)
• K. Yokoya (KEK)
• Q. Yue (Tsinghua U.)
• D. Zerwas (LAL Orsay)
• C. Zhang (IHEP Beijing)
• J. Zhang (IHEP Beijing)
• L. Zhang (Tsinghua U.)
• Y. Zhang (CNRS)
• Z. Zhang (Ningbo U.)
• K. Zhu (IHEP Beijing)
• B. Zitzer (McGill U.)
• H. Zong (Nanjing U.)
• K. Zuber (Dresden, Tech. U.)
• K. Zurek (LBNL)
• R.M. Zwaska (FNAL)
4. Naming scheme for hadrons
We introduced in the 1986 edition [2] a new naming scheme for the hadrons. Changes from older terminology affected mainly the heavier mesons made of u, d, and s quarks. Otherwise, the only important change to known hadrons was that the F
±became the D
±s