1 Anomalies and the Standard Model

Similar documents
Standard Model of Particle Physics

Theoretical Particle Physics FYTN04: Oral Exam Questions, version ht15

Gauge theories and the standard model of elementary particle physics

Concepts in Theoretical Physics

Extensions of the Standard Model (part 2)

Weak Interactions: towards the Standard Model of Physics

Physics Department, Southampton University Highfield, Southampton, S09 5NH, U.K.

Particle Physics. Michaelmas Term 2011 Prof Mark Thomson. Handout 7 : Symmetries and the Quark Model. Introduction/Aims

STRING THEORY: Past, Present, and Future

Introduction to SME and Scattering Theory. Don Colladay. New College of Florida Sarasota, FL, 34243, U.S.A.

arxiv: v2 [hep-ph] 20 Jun 2013

How To Teach Physics At The Lhc

Introduction to Elementary Particle Physics. Note 01 Page 1 of 8. Natural Units

Contents. Goldstone Bosons in 3He-A Soft Modes Dynamics and Lie Algebra of Group G:

Spontaneous symmetry breaking in particle physics: a case of cross fertilization

A SUSY SO(10) GUT with 2 Intermediate Scales

Particle Physics. The Standard Model. A New Periodic Table

The standard model of particle physics

Phase Transitions in the Early Universe

SUSY Breaking and Axino Cosmology

arxiv: v1 [hep-ph] 28 Jun 2010

How To Find The Higgs Boson

Grid Computing for LHC and Methods for W Boson Mass Measurement at CMS

Vector-like quarks t and partners

The Standard Model of Particle Physics - II

Selected Topics in Elementary Particle Physics ( Haupt-Seminar )

The Standard Model and the LHC! in the Higgs Boson Era Juan Rojo!

Feynman diagrams. 1 Aim of the game 2

Periodic Table of Particles/Forces in the Standard Model. Three Generations of Fermions: Pattern of Masses

Prospects for t t resonance searches at ATLAS

The Higgs sector in the MSSM with CP-phases at higher orders

UN PICCOLO BIG BANG IN LABORATORIO: L'ESPERIMENTO ALICE AD LHC

Scalar Mediated Fermion Masses for Technicolor

High Energy Physics. Lecture 4 More kinematics and a picture show of particle collisions

0.33 d down c charm s strange t top b bottom 1 3

Middle East Technical University. Studying Selected Tools for HEP: CalcHEP

Top rediscovery at ATLAS and CMS

Directed by: Prof. Yuanning Gao, IHEP, Tsinghua University Prof. Aurelio Bay, LPHE, EPFL

A Study of the Top Quark Production Threshold at a Future Electron-Positron Linear Collider

THREE QUARKS: u, d, s. Precursor 2: Eightfold Way, Discovery of Ω - Quark Model: first three quarks and three colors

Extraction of Polarised Quark Distributions of the Nucleon from Deep Inelastic Scattering at the HERMES Experiment

The Standard Model Higgs Boson

arxiv:hep-ph/ v1 17 Oct 1993

Axion/Saxion Cosmology Revisited

Gravity and running coupling constants

Beyond the Standard Model. A.N. Schellekens

The Higgs Boson. Linac08 Victoria BC, Canada CANADA S NATIONAL LABORATORY FOR PARTICLE AND NUCLEAR PHYSICS

Search for a heavy gauge boson W in the final state with electron and large ET. s = 7 TeV

Measurement of low p T D 0 meson production cross section at CDF II

Search for Dark Matter at the LHC

1 Introduction. 1 There may, of course, in principle, exist other universes, but they are not accessible to our

Search for solar axions with the CCD detector at CAST (CERN Axion Solar Telescope)

The Standard Model of Particle Physics. Tom W.B. Kibble Blackett Laboratory, Imperial College London

Looking for Magnetic Monopoles AT The Large Hadron Collider. Vicente Vento Universidad de Valencia-IFIC

Kinematic Tau Reconstruction and Search For The Higgs Boson in Hadronic Tau Pair Decays with the CMS Experiment

Bounding the Higgs width at the LHC

QCD MADE SIMPLE Quantum chromodynamics,

About the Author. journals as Physics Letters, Nuclear Physics and The Physical Review.

FINDING SUPERSYMMETRY AT THE LHC

arxiv:hep-ph/ v2 4 Oct 2003

Physics for the 21 st Century. Unit 1: The Basic Building Blocks of Matter. Bonnie Fleming and Mark Kruse

Transcription:

1 Anomalies and the Standard Model The Glashow-Weinberg-Salam model of the electroweak interactions has been very successful in explaining a wide range of experimental observations. The only major prediction of the model that remains to be verified experimentally is the existence of the Higgs boson. The GWS is based on SU(2) L U(1) Y gauge symmetry. A weak isospin triplet of massless W bosons couples to left-handed massless quarks and leptons. A weak isospin singlet massless gauge boson B couples to weak hypercharge of massless fermions. The gauge covariant derivative acting on any field takes the form D µ = µ iga a µt a ig Y B µ, where T a is the SU(2) representation matrix of the field and Y is its hypercharge. The W and B bosons also couple to a complex weak isospin doublet scalar field called the Higgs field. The potential of the Higgs field is chosen so that the vacuum breaks the global SU(2) L U(1) Y symmetry. This potentially results in three massless Goldstone bosons, but because of the Higgs mechanism, the Goldstone bosons disappear and three of the gauge fields acquire mass as physical W ± and Z 0 states. The one remaining massless gauge boson is the photon of QED. The Higgs mechanism also allows for the fermions to acquire mass. However, the values of these masses are not fixed by the theory, which allows for one free parameter for each type of fermion. 1

1 ANOMALIES AND THE STANDARD MODEL Figure 1: Gross and Jackiw showed that anomalies spoil the renormalizability of gauge theories. 2

2 QUANTUM NUMBERS OF QUARKS AND LEPTONS 2 Quantum Numbers of Quarks and Leptons Unlike the gluons of QCD which couple only to quarks, the GWS gauge bosons couple to leptons and quarks. The lepton and quark fields are decomposed into left and right handed components. components assigned to weak isospin doublets: ( ) ( ) νe u E L = e, Q L =. d L L The left-handed The upper and lower components have weak isospoin ± 1 2. The right-handed fields are assigned to weak isospin singlets: e R, u R, d R. For a long time it was believed that the neutrinos were strictly massless and purely left-handed. Observations of neutrino oscillations have opened the possibility that neutrinos might have mass. Each of these particles has an electric charge that is a multiple Q of the charge of the proton. Hypercharge quantum number Y values are then assigned so that the electric charges come out right according to the relation Q = T z + Y. This requires the following assignments: Y EL = 1 2, Y Q L = + 1 6, Y e R = 1, Y ur = + 2 3, Y d R = 1 3. 3

3 ANOMALY CANCELLATION REQUIREMENT 3 Anomaly Cancellation Requirement Because QCD is invariant under parity, the chiral current anomaly does not affect perturbative QCD. The neutral pion is a pseudo Goldstone boson of broken chiral symmetry. This is a non-perturbative problem in which the chiral anomaly plays and essential part. The GWS model is not symmetric under parity, and the W and Z bosons couple directly to chiral currents at the perturbative level. Soon after the model was introduced, Gross and Jackiw, among many others, realized such perturbative anomalies would make the GWS model non-renormalizable unless the quantum numbers of the fermions were such that all potential pertubative anomalies cancelled. The chiral anomaly is a disease of one-loop fermion triangle diagrams at least one of the three vertices involves the chiral Dirac matrix γ 5. Diagrams that can spoil renormalizablity are shown in Fig. 2. For each type, the sum of the two diagrams with the fermions circulating in opposite directions must be added. From the Feynman rules, the grouptheoretical factors involving the weak isopin and strong color matrices, and the weak hypercharges, can be factored out. The theory will be renormalizable if each such factor vanishes. For diagrams involving one U(1) current and 2 SU(3) currents, the overall factor is γ 5 Tr [ t a t b Y ] 1 = γ 5 2 δab ( ) L Y q, q where the sum runs over quarks q with a sign for the left-handed contributions. Evaluating the sum for 4

3 ANOMALY CANCELLATION REQUIREMENT Figure 2: From Peskin and Schroeder 5

4 ANOMALY CANCELLATION IN Z 0 PRODUCTION AT THE LHC the light u and d quarks gives ( 1) 2 1 ( ) 2 6 + + 3 ( 1 ) 3 = 0. Diagrams with a U(1) current and 2 SU(2) currents involve only left-handed fields ( ( 1) 1 ) ( + ( 1) 3 1 ) = 0, 2 6 where the quark contribution has been summed over the 3 colors. 4 Anomaly Cancellation in Z 0 Production at the LHC Huge numbers of W and Z bosons will be produced in pp collisions at the LHC. Because the masses of the W and Z bosons are large compared with the masses of the quark and gluon constituents in the colliding hadrons, it is generally a good approximation to assume that the quarks are massless in computing the production cross sections for these electroweak bosons at high energies. An exception, of course is the top quark, whose mass m t = 174 GeV, is approximately twice as large as that of the W or Z. Top quarks in loops pose a delicate problem because the Standard Model is renormalizable only if the left-handed quarks occur in SU(2) L doublets. Diagrams with quark triangle loops are shown in Fig. 3. 6

4 ANOMALY CANCELLATION IN Z 0 PRODUCTION AT THE LHC Figure 3: R. Gonsalves, J. Paw lowski, and C.-F. Wai, Phys. Rev. D 40, 2245 (1989). 7

4 ANOMALY CANCELLATION IN Z 0 PRODUCTION AT THE LHC It is important to evaluate the top-quark-mass contributions to measurable cross sections at LHC energies, in particular the W and Z transverse momentum distributions. Fig. 4 shows the Z transverse-momentum distribution at Tevatron and LHC energies including quark-triangle diagrams. Quark masses are taken into account using a simple threshold prescription by inserting a step function θ(q 2 T 4m2 f ) into sums over quark flavors f in the subprocess cross sections. There is a significant change in the shape of the distribution at LHC energies due specifically to the virtual triangle-anomaly diagrams. Because the triangle-anomaly contributions are comparable in magnitude to the O(α 2 s) QCD radiative corrections, it is essential to include the top and bottom quark masses in the virtual triangle diagram contributions. Homework Problem Compute the group theoretical factors and show that the anomalies cancel in each of the 10 types of triangle diagrams in the Standard Model. 8

4 ANOMALY CANCELLATION IN Z 0 PRODUCTION AT THE LHC 10 0 Z Transverse Momentum Distribution at the LHC and the Tevatron LHC: S 1/2 =14.0 TeV 10-1 LHC: No Virtual Triangle 10-2 Tevatron S 1/2 = 1.96 TeV Tevatron: No Virtual Triangle d!/dq 2 T (nb/gev2 ) 10-3 10-4 10-5 10-6 10-7 10-8 0 20 40 60 80 100 120 140 160 180 200 Q T (GeV) Figure 4: Triangle diagram contributions to the Z 0 transverse momentum distribution at the Tevatron and the LHC 9

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information