Figures from 2023 edition of RPP
These figures are licensed under the
CC BY-NC 4.0
license. Please give credit to the PDG citation.
R.L. Workman
et al.
(Particle Data Group),
Prog. Theor. Exp. Phys.
2022
, 083C01 (2022)
and 2023 update
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CONTENT LIST
Introduction
Constants, Units, Atomic and Nuclear Properties
Standard Model and Related Topics
Astrophysics and Cosmology
Experimental Methods and Colliders
Mathematical Tools
Gauge Bosons
Leptons
Quarks
Mesons
Baryons
Searches
Introduction Figures:
History Plots
Fig. 1
Constants, Units, Atomic and Nuclear Properties Figures:
Electromagnetic relations
Fig. 7.1
Standard Model and Related Topics Figures:
Quantum chromodynamics
Fig. 9.1T
Fig. 9.1B
Fig. 9.2
Fig. 9.3
Fig. 9.4
Fig. 9.5
Electroweak model and constraints on new physics
Fig. 10.1
Fig. 10.2
Fig. 10.3
Fig. 10.4
Fig. 10.5
Fig. 10.6
Higgs boson physics, Status of
Fig. 11.1
Fig. 11.2L
Fig. 11.2R
Fig. 11.3
Fig. 11.4
Fig. 11.5
Fig. 11.6
Fig. 11.7
Fig. 11.8
Fig. 11.9
Fig. 11.10
Fig. 11.11
Fig. 11.12
Fig. 11.13
Fig. 11.14
Fig. 11.15
Fig. 11.16L
Fig. 11.16R
Fig. 11.17
CKM quark-mixing matrix
Fig. 12.1
Fig. 12.2
CP violation in the quark sector
Fig. 13.1
Fig. 13.2
Fig. 13.3
Neutrino mass, mixing, and oscillations
Fig. 14.1
Fig. 14.2
Fig. 14.3
Fig. 14.4
Fig. 14.5TL
Fig. 14.5TC
Fig. 14.5TR
Fig. 14.5BL
Fig. 14.5BC
Fig. 14.6L
Fig. 14.6R
Fig. 14.7
Fig. 14.8L
Fig. 14.8C
Fig. 14.8R
Fig. 14.9
Fig. 14.10L
Fig. 14.10R
Fig. 14.11
Fig. 14.12
Quark model
Fig. 15.1
Fig. 15.2
Fig. 15.3
Fig. 15.4
Fig. 15.5
Fig. 15.6
Fig. 15.7
Fig. 15.8
Fig. 15.9
Fig. 15.10
Fig. 15.11
Fig. 15.12
Fig. 15.13
Fig. 15.14
Fig. 15.15
Lattice quantum chromodynamics
Fig. 17.1
Structure functions
Fig. 18.1
Fig. 18.2
Fig. 18.3
Fig. 18.4T
Fig. 18.4B
Fig. 18.5
Fig. 18.6
Fig. 18.7
Fig. 18.8
Fig. 18.9L
Fig. 18.9R
Fig. 18.10
Fig. 18.11
Fig. 18.12
Fig. 18.13
Fig. 18.14
Fig. 18.15
Fig. 18.16
Fig. 18.17
Fig. 18.18
Fragmentation functions in e+ e-, ep, and pp collisions
Fig. 19.1
Fig. 19.2a
Fig. 19.2b
Fig. 19.3a
Fig. 19.3b
Fig. 19.4
Fig. 19.5
Fig. 19.6
Fig. 19.7
Fig. 19.8
Fig. 19.9a
Fig. 19.9b
Fig. 19.10
Fig. 19.11T
Fig. 19.11B
Fig. 19.12a
Fig. 19.12b
High energy soft QCD and diffraction
Fig. 20.1
Fig. 20.2
Fig. 20.3
Fig. 20.4
Fig. 20.5
Fig. 20.6L
Fig. 20.6R
Fig. 20.7
Fig. 20.8
Fig. 20.9
Fig. 20.10L
Fig. 20.10R
Fig. 20.11L
Fig. 20.11R
Fig. 20.12L
Fig. 20.12R
Fig. 20.13L
Fig. 20.13R
Fig. 20.14
Fig. 20.15L
Fig. 20.15R
Fig. 20.16L
Fig. 20.16R
Fig. 20.17L
Fig. 20.17R
Fig. 20.18
Tests of conservation laws
Fig. 1
Fig. 2
Fig. 3L
Fig. 3R
Fig. 4
Fig. 5
Astrophysics and Cosmology Figures:
Big-bang cosmology
Fig. 22.1
Fig. 22.2
Fig. 22.3
Fig. 22.4
Fig. 22.5
Inflation
Fig. 23.1
Fig. 23.2
Fig. 23.3
Fig. 23.4
Fig. 23.5
Big-bang nucleosynthesis
Fig. 24.1
Cosmological parameters
Fig. 25.1
Fig. 25.2
Neutrinos in cosmology
Fig. 26.1L
Fig. 26.1R
Fig. 26.2L
Fig. 26.2R
Dark Matter
Fig. 27.1
Fig. 27.2
Dark Energy
Fig. 28.1
Fig. 28.2
Fig. 28.3
Cosmic microwave background
Fig. 29.1
Fig. 29.2
Fig. 29.3
Fig. 29.4
Fig. 29.5
Fig. 29.6
Cosmic rays
Fig. 30.1
Fig. 30.2
Fig. 30.3
Fig. 30.4
Fig. 30.5
Fig. 30.6L
Fig. 30.6R
Fig. 30.7
Fig. 30.8
Fig. 30.9
Fig. 30.10
Fig. 30.11L
Fig. 30.11C
Fig. 30.11R
Fig. 30.12
Fig. 30.13
Fig. 30.14
Fig. 30.15
Fig. 30.16
Experimental Methods and Colliders Figures:
Passage of particles through matter
Fig. 34.1
Fig. 34.2
Fig. 34.3
Fig. 34.4
Fig. 34.5
Fig. 34.6
Fig. 34.7
Fig. 34.8
Fig. 34.9
Fig. 34.10
Fig. 34.11
Fig. 34.12
Fig. 34.13
Fig. 34.14
Fig. 34.15
Fig. 34.16
Fig. 34.17
Fig. 34.18
Fig. 34.19
Fig. 34.20
Fig. 34.21
Fig. 34.22
Fig. 34.23
Fig. 34.24
Fig. 34.25
Fig. 34.26
Fig. 34.27
Particle detectors at accelerators
Fig. 35.1
Fig. 35.2
Fig. 35.3
Fig. 35.4
Fig. 35.5
Fig. 35.6
Fig. 35.7
Fig. 35.8
Fig. 35.9
Fig. 35.10
Fig. 35.11
Fig. 35.12
Fig. 35.13
Fig. 35.14
Fig. 35.15
Fig. 35.16
Fig. 35.17L
Fig. 35.17R
Fig. 35.18
Fig. 35.19
Fig. 35.20
Fig. 35.21
Fig. 35.22L
Fig. 35.22R
Fig. 35.23
Fig. 35.24
Fig. 35.25
Fig. 35.26
Fig. 35.27L
Fig. 35.27R
Fig. 35.28
Fig. 35.29
Fig. 35.30
Fig. 35.31
Fig. 35.32
Fig. 35.33
Fig. 35.34
Fig. 35.35L
Fig. 35.35R
Fig. 35.36L
Fig. 35.36R
Fig. 35.37
Fig. 35.38
Fig. 35.39
Fig. 35.40
Particle detectors for non-accelerator physics
Fig. 36.1
Fig. 36.2
Fig. 36.3L
Fig. 36.3R
Fig. 36.4
Fig. 36.5
Fig. 36.6L
Fig. 36.6R
Fig. 36.7
Fig. 36.8
Fig. 36.9L
Fig. 36.9R
Fig. 36.10
Radioactivity and radiation protection
Fig. 37.1
Fig. 37.2
Fig. 37.3
Fig. 37.4
Fig. 37.5
Fig. 37.6
Mathematical Tools Figures:
Statistics
Fig. 40.1
Fig. 40.2
Fig. 40.3
Fig. 40.4
Fig. 40.5
Machine Learning
Fig. 41.1L
Fig. 41.1R
Fig. 41.2
Fig. 41.3
Fig. 41.4
Fig. 41.5
Fig. 41.6
Fig. 41.7
Fig. 41.8
Fig. 41.9
Fig. 41.10
Fig. 41.11
Monte Carlo techniques
Fig. 42.1
Fig. 42.2
Monte Carlo event generators
Eq. CR
Fig. 43.1
Fig. 43.2
Fig. 43.3
Clebsch-Gordan coefficints, spherical harmonics, and d functions
Fig. 46.1
Kinematics
Fig. 49.1
Fig. 49.2
Fig. 49.3
Fig. 49.4
Fig. 49.5
Fig. 49.6
Fig. 49.7
Resonances
Fig. 50.1
Fig. 50.2
Fig. 50.3
Fig. 50.4
Fig. 50.5
Fig. 50.6
Neutrino cross section measurements
Fig. 52.1
Plots of cross sections and related quantities
Fig. 53.1
Fig. 53.2
Gauge Bosons Figures:
Mass and width of the
W
boson
Fig. 54.1
Fig. 54.2
Fig. 54.3
Leptons Figures:
Muon anomalous magnetic moment
Fig. 56.1a
Fig. 56.1b
Fig. 56.1c
Fig. 56.1d
Fig. 56.2
tau branching fractions
Fig. 58.1
Fig. 58.2
Fig. 58.3
Fig. 58.4
Quarks Figures:
Quark masses
Fig. 60.1
Fig. 60.2
Fig. 60.3
Top quark
Fig. 61.1
Fig. 61.2
Mesons Figures:
Form factors for semileptonic kaon, radiative pion and kaon decays
Fig. 62.1
Spectroscopy of light meson resonances
Fig. 63.1
Fig. 63.2
Fig. 63.3
Scalar mesons below 1 GeV
Fig. 64.1
Fig. 64.2
Fig. 64.3
Fig. 64.4
Charged kaon mass
Fig. 1
Rare kaon decays
Fig. 65.1
Fig. 65.2
Fig. 65.3
CPT invariance tests in neutral kaon decay
Fig. 66.1
CP-violation in KL decays
Fig. 68.1
Fig. 68.2
Fig. 68.3
D0--Dbar0 mixing
Fig. 70.1L
Fig. 70.1R
Ds+ branching fractions
Fig. 71.1
Leptonic decays of charged pseudoscalar mesons
Fig. 72.1
Polarization is B decays
Fig. 74.1
B0--Bbar0 mixing
Fig. 75.1L
Fig. 75.1R
Fig. 75.2
Fig. 75.3
Semileptonic b-hadron decays and determination of V
cb
and V
ub
Fig. 76.1
Fig. 76.2
Determination of CKM angles from B hadrons
Fig. 77.1
Fig. 77.2
Fig. 77.3
Fig. 77.4
Spectroscopy of mesons containing two heavy quarks
Fig. 78.1
Fig. 78.2
Fig. 78.3
Fig. 78.4
Fig. 78.5
Fig. 78.6
Fig. 78.7
The charmonium system
Fig. 1
The bottomonium system
Fig. 1
Baryons Figures:
N and Delta resonances
Fig. 81.1L
Fig. 81.1R
Fig. 81.2T
Fig. 81.2M
Fig. 81.2B
Fig. 81.3T
Fig. 81.3M
Fig. 81.3B
Lambda and Sigma resonances
Fig. 82.1
Pentaquarks
Fig. 84.1
Fig. 84.2
Fig. 84.3
Hypothetical Particles and Concepts Figures:
W'
-boson searches
Fig. 86.1L
Fig. 86.1R
Fig. 86.2L
Fig. 86.2R
Z'
-boson searches
Fig. 87.1L
Fig. 87.1R
Fig. 87.2
Supersymmetry part I (theory)
Fig. 88.1
Supersymmetry part II (experiment)
Fig. 89.1
Fig. 89.2
Fig. 89.3L
Fig. 89.3R
Fig. 89.4L
Fig. 89.4R
Fig. 89.5L
Fig. 89.5R
Fig. 89.6
Fig. 89.7
Fig. 89.8L
Fig. 89.8R
Fig. 89.9
Fig. 89.10L
Fig. 89.10R
Fig. 89.11L
Fig. 89.11R
Fig. 89.12
Fig. 89.13L
Fig. 89.13R
Fig. 89.14
Axions and other similar particles
Fig. 90.1
Fig. 90.2
Fig. 90.3
Fig. 90.4
Fig. 90.5
Quark and lepton compositeness, searches for
Fig. 91.1
Fig. 91.2
Fig. 91.3
Fig. 91.4L
Fig. 91.4R
Dynamical electroweak symmetry breaking: Implications of the H
0
Fig. 92.1L
Fig. 92.1R
Fig. 92.2L
Fig. 92.2R
Fig. 92.3L
Fig. 92.3R
Fig. 92.4L
Fig. 92.4R
Fig. 92.5
Grand Unified Theories
Fig. 93.1L
Fig. 93.1R
Magnetic monopoles
Fig. 95.1L
Fig. 95.1R
Fig. 95.2