Nuclear and Particle Physics Franz Muheim 1
Nuclear & Particle PhysicsNuclear & Particle PhysicsJunior HonoursJunior Honours
Lecturer: Dr Franz MuheimEmail: [email protected]: JCMB 4407Course web page:http://www.ph.ed.ac.uk/~muheim/teaching/np3
Recommended Textbooks:Particle Physics – B.R. Martin & G. Shaw,
2nd edition (Wiley 1997)Introduction to High Energy Physics -
D.H. Perkins, 4th edition (CUP 2000) Introduction to Elementary Particles -
D. Griffiths (Wiley 1987)Quarks and Leptons – F. Halzen & A.D. Martin
(Wiley 1984)Review of Particles Physics
http://durpdg.dur.ac.uk/lbl
Simple
Advanced
Nuclear and Particle Physics Franz Muheim 2
Particle Physics Particle Physics Course OutlineCourse Outline
Introduction & Fundamental ParticlesQuarks and Leptons, PhotonsNatural Units, Kinematics
Feynman diagramsAntiparticlesElectromagnetic Interaction
Interaction with MatterParticle Detectors, Accelerators, Experiments
QuarksMeson and BaryonsIsospin, Strangeness
Strong InteractionColour, GluonsConfinement, running coupling constants
Symmetries & Conservation LawsBaryon/lepton number, charge and parity
Weak InteractionMuon and tau decayHeavy quarks, CKM mechanism
NeutrinosNeutrino Mass and Oscillations
Electroweak TheoryW and Z bosons, LEPSpontaneous Symmetry Breaking, Higgs
Nuclear and Particle Physics Franz Muheim 3
MotivationMotivation
Big Bang:Matter and Antimatter were created
in equal amountsWhy does the Universe look like
this not that???
What’s the interest in Particle Physics?Human quest for knowledgeRelation to cosmology (matter vs antimatter,
dark matter, dark energy) “Journey to the centre of the Universe” - F CloseTechnology - CERN
The world's largest particle physics laboratory ... where the web was born! Material science, e.g. µSR, Medical, e.g. PET
Nuclear and Particle Physics Franz Muheim 4
http://particleadventure.org/particleadventure/http://www.cpepweb.org/particles.html
http://www2.slac.stanford.edu/vvc/Default.htmhttp://public.web.cern.ch/public/
Nuclear and Particle Physics Franz Muheim 5
The Questions of The Questions of Particle PhysicsParticle Physics
What is matter made of?Greeks: earth, air, water, fireatomos (ατοµοσ)
Atoms
Nucleus & electrons
Protons, neutrons
Quarks and electrons
How do these particles interact?What are electromagnetic forces?What holds nucleus together?What causes radioactivity?How does gravity act at such large distances?
Particle Physics
Nuclear and Particle Physics Franz Muheim 6
Standard Model ofStandard Model ofParticle PhysicsParticle Physics
“A Briefest Introduction”Particle Physics
Study of Nature at shortest distance and timesMatter
Fundamental constituents of Universe -elementary particles
ForcesBasic forces of Nature – interactions between elementary particles
Aim to find simplest classification of fundamental particles and their interactions
MatterTwo types of fermions - spin ½Leptons: e-, νQuarks: u, d proton = (uud)Antimatter: positron (e+), antiproton
ForcesInteractions between quarks and leptonsare mediated by exchange of gauge bosons – spin 1
Electromagnetic photonsStrong gluonsWeak W and ZGravity graviton
Nuclear and Particle Physics Franz Muheim 7
The ElectronThe Electron
Discovered in 1897 by J.J. Thomson
Electron - Elementary ParticlePoint-like: size < 10-6 fm (10-21 m)Stable: lifetime > 4.6 1026 yrs
Electric chargeqe = -e = -1.60217653(14)·10-19 C
Massme = 0.510998918(44) MeV = 9.11·10-31 kg
SpinIntrinsic property: spin ½Fermion, satisfies Pauli Exclusion Principle
Nuclear and Particle Physics Franz Muheim 8
The PhotonThe Photon
Discovered in 1924 by A.H. ComptonPhoton - Elementary Particle
Pointlike: size < 10-6 fm (10-21 m)Stable:
Electric chargeNo charge: qγ < = 5·10-30 e
MassMass-less: mγ < 6 ·10-17 eV
EnergyE = hν = hc/λ
SpinIntrinsic property: spin 1Boson, satisfies Bose-Einstein statistics
Compton effectPhoton scatters offelectron (at rest)
'' ee +→+ γγ
θ γ
eee
ee
ee
ee
EppE
pEEEEmE
θθθ
θθ
,,Eliminatesinsin'
coscos')frameLab('
onconservatimomentumandEnergy
=+=+=+
( )
wavelengthCompton
1086.3where
)cos1('
cos11
1'
13
2
mcm
cmEEE
ec
c
e
−⋅==
−+=
−+=
hλ
θλλλ
θγ
Nuclear and Particle Physics Franz Muheim 9
Elementary ParticlesElementary Particles
“What you already know”“ Explain almost all of Atomic & Nuclear Physics”
Constituents of Matter:Four spin ½ particles - fermions
LeptonsElectron and neutrino
QuarksNucleons are composite 3-quark statesproton (uud)neutron (udd)
Example - Beta decay:
Particle symbol charge typeElectron e- -1 leptonNeutrino νe 0 leptonUp-quark u +2/3 quark
Down-quark d -1/3 quark
eeud
eepn
ν
ν
+−+→
+−+→
LeptonsLeptons
QuarksQuarks
Nuclear and Particle Physics Franz Muheim 10
Generations of Generations of Quarks and LeptonsQuarks and Leptons
Nature replicates itselfis not that simple3 generations of fundamental fermions
Ordinary Matterbuilt from 1st generationLepton (νe, e-) and quark (u,d) doublet
Higher generationscopies of (νe, e-, u, d)Undergo identical interactionsOnly difference in mass of particleshigher generations are heavier
Why 3 generations?Symmetry/structure not understood!
First Generation 2nd Generation 3rd Generation Charge e
Electron Neutrino
Tau neutrino
TauTop quark
Bottom quark
ντ
Electron
0
τ-tUp quark
b
-1
Down quark
+2/3
-1/3
νe Muonneutrino
e-u
d
MuonCharm quark
Strange quark
νµ
µ-c
s
Nuclear and Particle Physics Franz Muheim 11
LeptonsLeptons
Particles that do not interact via strong force6 distinct flavoursElectron and Neutrino partners
fermions - spin ½Additive quantum numbers - Charge q, Lepton family number Le, Lµ, Lτ
MuonLike electrons, but 200 times heavier“Who ordered that?” I.I. RabiUnstable – Lifetime: 2.2 µsSeparate muon-neutrino partner
TauEven heavier - me x 3500Unstable – Lifetime: 291 fsPartner is tau-neutrino
TauTau
MuonMuon
ElectronElectron Electron NeutrinoElectron Neutrino
Muon NeutrinoMuon Neutrino
Tau NeutrinoTau Neutrino
Nuclear and Particle Physics Franz Muheim 12
Lepton PropertiesLepton Properties
Antiparticleslepton antilepton partner with equal mass, but opposite charge opposite additive quantum numbers Example:Positron (e+) or anti-electrondiscovered in 1931 by Anderson
Lepton family numberLe, Lµ, Lτ are conservedin all reactions
Charged Leptons: e-, µ-, τ-Interact via electromagnetic and weak force
NeutrinosInteract only via weak forcealmost massless - Neutrino oscillationsνe and anti-νe are different particles
forbiddenforbidden
allowed
allowed
+−++
++
++
−−
→
→
→
→
eeee
e
e
e
e
µ
γµ
ννµ
ννµ
µ
µ
Positron track
Nuclear and Particle Physics Franz Muheim 13
QuarksQuarks
Quark PropertiesFermions - spin ½Fractional charge: (+2/3 e or -1/3 e)6 distinct flavours
for comparison proton mass mp = 938 MeV/c2
ColourQuarks come in three colours“Red”, “green” or “blue”All hadrons are “colourless”
Quark InteractionsQuarks undergo strong, electromagnetic andweak interactions (also gravity)
ConfinementQuarks are confined in hadrons
u, d, s, c, b, tu, d, s, c, b, t
Nuclear and Particle Physics Franz Muheim 14
Hadrons, Mesons, BaryonsHadrons, Mesons, Baryons
HadronsSingle free quarks have never been observedQuarks are locked inside hadronsHadrons are bound states of quarkse.g. (qqq) or (q anti-q)Charge of hadron - always integer multiple of eTwo types of hadrons – mesons and baryons
MesonsBound states of a quark anti-quark pairBosons - spin 0, 1, 2, …e.g. pions
BaryonsThree quark bound states Fermions – spin ½, 3/2, …e.g. proton = (uud), neutron = (udd)Anti-baryons – e.g. anti-proton = (uud)
)(2
1)()(
0 dduu
dudu
−=
== −+
π
ππ
HadronsHadrons
Baryons = qqqBaryons = qqq
Mesons = qqMesons = qq-
---
Nuclear and Particle Physics Franz Muheim 15
InteractionsInteractions
Classical InteractionsElectromagnetism and gravity… act upon another at a distance … … great absurdity … Newton
Interactions/Forces in Particle Physicsquarks and leptons interact via the exchange of gauge bosons
Gauge bosonsVector bosons – Spin 1Mediators of strong (gluon),electromagnetic (photon),weak (Z0 & W±) interaction
Force Gauge Boson Symbol Chargee
MassGeV/c2
Relative Strength
Strong 8 gluons g 0 0
0
91.187680.425
0
1
Electro magnetic
Photon γ 0 10-2
Weak Intermediate vector bosons
Z0
W±0±1
~10-7
Gravity Graviton g 0 ~10-40
Gauge BosonsGauge Bosons
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Fundamental ForcesFundamental Forces
Strong force (gluon)Quarks (colour charge) onlyHolds hadrons (baryons and mesons) and nuclei (A
ZX) togetherElectromagnetic force (γ)
All charged particlesResponsible for chemistry and biology
Weak interaction (Z0 & W±)All quarks and leptons causes radioactive decays,fission, fusion“Exchange of W± bosons makes the sun shine.”
Gravity (graviton)Very weak at short distance Negligible effects in particle physicsdominant at large distance
“While gravity keeps you from flying off the earth, theelectromagnetic force (mediated by the exchange ofphotons) keeps you from falling towards its centre.”
Strong force (gluon)Strong force (gluon)
Electromagnetic force (γ)Electromagnetic force (γ)
Weak interaction (Z0 & W±)Weak interaction (Z0 & W±)
Gravity (graviton)Gravity (graviton)
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SummarySummary
Describes accurately all experimental dataMany open questions, e.g. origin of mass
MatterThree generations of fundamental particles quarks and leptons - spin ½ fermions
Quarks confined in hadrons, e.g. proton = (uud)Antimatter: positron (e+), antiproton
ForcesInteractions between quarks and leptonsmediated by exchange of spin 1 - gauge bosons
x
Standard Model of Particle PhysicsStandard Model of Particle Physics
Leptons & Quarks Charge e
νe νµ ντ 0e- τ-
tb
u-1
+2/3d -1/3
µ-cs
0graviton gGravity0, ±1Z0, W±Weak
0photon γElectromagnetic
0gluons gStrongCharge [e]Gauge bosonInteraction
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