��������W�˜�ģ�͌�Փ-��2��

preface to the second edition
preface to the first edition
notation
1 the particle physicist's view of nature
1.1 introduction
1.2 the construction of the standard model
1.3 leptons
��1.4 quarks and systems of quarks
��1.5 spectroscopy of systems of light quarks
��1.6 more quarks
��1.7 quark colour
��1.8 electron scattering from nucleons
��1.9 particle accelerators
��1.10 units
2 lorentz transformations
��2.1 rotations, boosts and proper lorentz transformations
��2.2 scalars, contravariant and covariant four-vectors
��2.3 fields
��2.4 the levi-civita tensor
��2.5 time reversal and space inversion
3 the lagrangian formulation of mechanics
��3.1 hamilton's principle
��3.2 conservation of energy
��3.3 continuous systems
��3.4 a lorentz covariant field theory
��3.5 the klein-gordon equation
��3.6 the energy-momentum tensor
��3.7 complex scalar fields
4 classical electromagnetism
��4.1 maxwell's equations
��4.2 a lagrangian density for electromagnetism
��4.3 gauge transformations
��4.4 solutions of maxwell's equations
��4.5 space inversion
��4.6 charge conjugation
��4.7 intrinsic angular momentum of the photon
��4.8 the energy density of the electromagnetic field
��4.9 massive vector fields
5 the dirac equation and the dirac field
��5.1 the dirac equation
��5.2 lorentz transformations and lorentz invariance
��5.3 the parity transformation
��5.4 spinors
��5.5 the matrices
��5.6 making the lagrangian density real
6 free space solutions of the dirac equation
��6.1 a dirac particle at rest
��6.2 the intrinsic spin of a dirac particle
��6.3 plane waves and helicity
��6.4 negative energy solutions
��6.5 the energy and momentum of the dirac field
��6.6 dirac and majorana fields
��6.7 the e ] ] m limit, neutrinos
7 electrodynamics
��7.1 probability density and probability current
��7.2 the dirac equation with an electromagnetic field
��7.3 gauge transformations and symmetry
��7.4 charge conjugation
��7.5 the electrodynamics of a charged scalar field
��7.6 particles at low energies and the dirac magnetic moment
8 quantising fields: qed
��8.1 boson and fermion field quantisation
��8.2 time dependence
��8.3 perturbation theory
��8.4 renornmalisation and renormalisable field theories
��8.5 the magnetic moment of the electron
��8.6 quantisation in the standard model
9 the weak interaction: !ow energy phenomenology
��9.1 nuclear beta decay
��9.2 pion decay
��9.3 conservation of lepton number
��9.4 muon decay
��9.5 the interactions of muon neutrinos with electrons
10 symmetry breaking in model theories
��10.1 global symmetry breaking and goldstone bosons
��10.2 local symmetry breaking and the higgs boson
11 massive gauge fields
��11.1 su(2) symmetry
��11.2 the gauge fields
��11.3 breaking the su(2) symmetry
��11.4 identification of the fields
12 the weinberg����salam electroweak theory for leptons
��12.1 lepton doublets and the weinberg-salam theory
��12.2 lepton coupling to the w
��12.3 lepton coupling to the z
��12.4 conservation of lepton number and conservation of charge
��12.5 cp symmetry
��12.6 mass terms in : an attempted generalisation
13 experimental tests of the weinberg����salam theory
��13.1 the search for the gauge bosons
��13.2 the w bosons
��13.3 the z boson
��13.4 the number of lepton families
��13.5 the measurement of partial widths
��13.6 left-right production cross-section asymmetry and lepton decay symmetry of the z boson
14 the electromagnetic and weak interactions of quarks
��14.1 construction of the lagrangian density
��14.2 quark masses and the kobayashi-maskawa mixing matrix
��14.3 the parameterisation of the km matrix
��14.4 cp symmetry and the km matrix
��14.5 the weak interaction in the low energy limit
15 the hadronic decays of the z and w bosons
��15.1 hadronic decays of the z
��15.2 asymmetry in quark production
��15.3 hadronic decays of the w
16 the theory of strong interactions: quantum chromodynamics
��16.1 a local su(3) gauge theory
��16.2 colour gauge transformations on baryons and mesons
��16.3 lattice qcd and asymptotic freedom
��16.4 the quark-antiquark interaction at short distances
��16.5 the conservation of quarks
��16.6 isospin symmetry
��16.7 chiral symmetry
17 quantum chromodynamics: calculations
��17.1 lattice qcd and confinement
��17.2 lattice qcd and hadrons
��17.3 perturbative qcd and deep inelastic scattering
��17.4 perturbative qcd and e+e- collider physics
18 the kobayashi-maskawa matrix
��18.1 leptonic weak decays of hadrons
��18.2 |vud| and nuclear decay
��18.3 more leptonic decays
��18.4 cp symmetry violation in neutral kaon decays
��18.5 b meson decays and b,b mixing
��18.6 the cpttheorem