The Physics of the Z and W Bosons

The following sections are included:

• Preface

• Contents

The following sections are included:

• Weak interactions in the original Fermi approach

• Weak interactions and the intermediate vector bosons

• The Higgs mechanism in the local SU(2) gauge symmetry case

• Unification of weak and electromagnetic interactions in the Standard Model
  • The SU(2) × U(1) description of electroweak interactions
  • Gauge boson masses in the SU(2)_L × U(1)_YL scheme
  • The (W,Z) mass relationship and the ρ₀ parameter
  • Electroweak unification and weak neutral currents
  • Numerical prediction for the gauge boson masses in the Minimal Standard Model

• Z physics as a test of the MSM
  • The Higgs scalar mass in the MSM
  • A more complete formulation of the MSM
    • Inclusion of strong interactions
    • Masses of leptons and quarks
    • Family replication
  • Tests of the MSM at LEP1/SLC
  • Universality of weak interactions and number of fermion families

The following sections are included:

• Conventions, spinors and basic cross sections

• Chiral fermions and polarized cross sections in the one-photon exchange

• Interaction involving a Z boson

• Computation of Z partial widths

• Angular and polarization asymmetries

• Asymmetries in the vicinity of the Z pole

The following sections are included:

• Definition of physical input parameters and removal of infinities at one loop in e⁺e⁻ annihilation on Z resonance
  • The theoretical description at tree level
  • Renormalizability and gauge transformations in the MSM
  • Treatment of formally divergent quantities in e⁺e⁻ annihilation: the divergences at one loop
  • The dimensional regularization method
  • Definition of physical parameters: renormalization of m_W, m_Z
  • Charge renormalization and definition in the MSM
  • The ‘running’ of α_QED in the MSM

• Theoretical description of the Z physics observables at one loop in the MSM
  • Choice of the most convenient input parameters: definition of the physical G_F
  • Derivation of Sirlin's equation: introduction and denition of the fundamental parameter Δr
  • Calculation of Δr^(f): identification of four classes of physical effects
  • Numerical estimate of
  • Determination of Δr^W and calculation of the W mass
    • Numerical estimate of Δ₁(0)
    • Numerical estimate of
    • Numerical estimate of Δ₂
    • Calculation of the W mass

• Formulation of Z physics at one loop: introduction of the effective weak parameter sin²θ_W,eff
  • Operative definition of the electroweak mixing angle: the longitudinal polarization asymmetry
  • Calculation of sin²θ_W,eff at one loop: fermion pairs contributions to self-energies
  • Relationship between and m_Z
  • The Z leptonic width at one loop in the ‘fermion pairs’ approximation

• The complete expression of sin²θ_W,eff at one loop
  • A gauge-invariant classification of one-loop effects
  • Operative definition of sin² θ_W,eff the leptonic asymmetries at the Z peak.

• A two-parameters description of Z physics for final leptonic states
  • Complete expression of the Z leptonic width at one-loop
  • The Z peak leptonic observables in terms of the ε₁, ε₃ parameters
  • Dependence of the weak parameters ε₁, ε₃ on the Higgs mass
  • The ε₂ parameter and the complete expression of the W mass

The following sections are included:

• The rôle of the vertex in Z Physics
  • Calculation of the electroweak component of the vertex
  • Observable effects of the vertex at the Z peak: the large m_t limit
  • Operative definition of the vertex at the Z peak: the δ_bV parameter

• The rôle of strong interactions in Z physics
  • Strong interactions effects at the Z peak
  • Higher order strong coupling contributions

The following sections are included:

• LEP

• SLC

• Tevatron

• Beyond LEP, SLC and Tevatron: next colliders

• Detectors

The following sections are included:

• Initial state radiation in e⁺e⁻ collisions

• The reduced cross sections

• Luminosity

• Centre-of-mass energy calibration in e⁺e⁻ collisions

• Selection of hadronic and leptonic Z decays

• Measuring the Z lineshape parameters

The following sections are included:

• General properties of hadronic events at the Z

• Tagging Z decays to b and c quarks
  • Lepton tagging
  • Lifetime tagging
  • Reconstruction of charmed hadrons
  • Event shape tagging
  • Gluon splitting to heavy quarks

• R_b measurements
  • The single/double tag method
  • Multi-tag methods
  • R_b results

• R_c measurements
  • Single/double tag
  • Inclusive/exclusive tag
  • Lepton analyses
  • Charm counting
  • results

The following sections are included:

• Measurement of the left-right asymmetry (A_LR)

• Measurement of the tau polarization in Z decays

• Forward-backward asymmetries
  • Lepton forward-backward asymmetries
  • Heavy quark asymmetries
    • Lepton tagging
    • Inclusive measurements
    • Measurement of the jet charge asymmetry using all avours
    • D meson measurements at LEP
    • Heavy quark asymmetries: combined results and QCD corrections
    • HF asymmetries with polarized beams

• Interpretations
  • The determinations of sin² θ_W,eff
  • Extraction of the neutral current couplings

The following sections are included:

• W mass measurement at hadron colliders

• W production in e⁺e⁻ collisions

• W mass measurement in e⁺e⁻ collisions

• Triple gauge couplings
  • The e⁺e⁻ →W⁺W⁻ angular analysis and the W polarization
  • The effective TGC lagrangian and the couplings

The following sections are included:

• Top-quark properties

• Direct measurement of the top mass

• Electroweak constraints on the top mass

The following sections are included:

• Search for the Higgs boson before LEP

• Higgs production at LEP

• Searching the Higgs at LEP1

• Setting confidence levels

• Higgs searches at LEP2

• The Higgs mass from electroweak fits

• Model independent analysis of electroweak data

The authors of this book have described, for the benefit of the patient readers, some relevant aspects of the physics of the W and Z bosons. It has been shown that a gauge theory of electroweak interactions, also known as the Standard Model of electroweak interactions, describes all experimental features of W and Z physics. The experimental tests of the electroweak theory, ongoing since 30 years, have reached their mature stage, thanks to the precision measurements performed at LEP, SLC and Tevatron. Some of these measurements are of unprecedented precision; as an example it can be recalled that the mass of the Z boson is presently known with the precision of ten part over a million and it is one of the most precisely measured physical observables. As a consequence of this remarkable effort the electroweak theory has been tested at the one-loop level.

The following sections are included:

• Bibliography

• Index