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Lecture I: introduction to QCD
Marco van LeeuwenUtrecht University
Jyväskylä Summer School 2008
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Particle Data Group topical reviews http://pdg.lbl.gov/2004/reviews/contents_sports.html
QCD and jets: CTEQ web page and summer school lectures http://www.phys.psu.edu/~cteq/
Handbook of Perturbative QCD, Rev. Mod. Phys. 67, 157–248 (1995)http://www.phys.psu.edu/~cteq/handbook/v1.1/handbook.ps.gz
QCD and Collider Physics, R. K. Ellis, W. J. Sterling, D.R. Webber, Cambridge University Press (1996)
An Introduction to Quantum Field Theory, M. Peskin and D. Schroeder, Addison Wesley (1995)
Introduction to High Energy Physics, D. E. Perkins, Cambridge University Press, Fourth Edition (2000)
General QCD references
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What is QCD?
From: T. Schaefer, QM08 student talk
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QCD and hadronsQuarks and gluons are the fundamental particles of QCD(feature in the Lagrangian)
However, in nature, we observe hadrons:Color-neutral combinations of quarks, anti-quarks
Baryon multiplet Meson multiplet
Baryons: 3 quarks
I3 (u,d content)
S stra
ngen
ess
I3 (u,d content)
Mesons: quark-anti-quark
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Seeing quarks and gluons
In high-energy collisions, observe traces of quarks, gluons (‘jets’)
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How does it fit together?
S. Bethke, J Phys G 26, R27
Running coupling:s decreases with Q2
Pole at =
QCD ~ 200 MeV ~ 1 fm-1
Hadronic scale
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Asymptotic freedom and pQCD
At large Q2, hard processes: calculate ‘free parton scattering’
At high energies, quarks and gluons are manifest
gqqee
But need to add hadronisation (+initial state PDFs)
+ more subprocesses
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Low Q2: confinement
Lattice QCD potential
large, perturbative techniques not suitable
Lattice QCD: solve equations of motion (of the fields) on a space-time lattice by MC
String breaks, generate qq pair to reduce field energy
Bali, hep-lat/9311009
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Singularities in pQCD
Closely related to hadronisation effects
(massless case)
Soft divergence Collinear divergence
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Singularities in phase space
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How to picture a QCD event
MC event generators use this picture
Initial hard scatteringhigh virtuality Q2
generateshigh-pT partons
Followed by angle-ordered gluon
emissions:fragmentation
At hadronic scale:hadronisation prescription
(e.g. clustering in HERWIG)
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QCD matter
Bernard et al. hep-lat/0610017
Tc ~ 170 -190 MeV
Energy density from Lattice QCD
Deconfinement transition: sharp rise of energy density at Tc
Increase in degrees of freedom: hadrons (3 pions) -> quarks+gluons (37)
c ~ 1 GeV/fm3
4gTg: deg of freedom
Nuclear matterQuark Gluon Plasma
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QCD phase diagram
Tem
per
atu
re
Confined hadronic
matter
Quark Gluon Plasma(Quasi-)free quarks and gluons
Nuclear matter
Neutron stars
Elementary collisions(accelerator physics)
High-density phases?
Ea
rly u
niv
ers
e
Critical
Point
qqB ~
Bulk QCD matter: T and B drive phases
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Heavy quarks
Definition: heavy quarks, m >> QCD
Charm: m ~ 1.5 GeVBottom: m ~ 4.5 GeVTop: m ~ 170 GeV
M. Cacciari, CTEQ-MCNet summer school 2008
Complications exist: QCD, EW corrections; quark mass defined in different ways
‘Perturbative’ hadronisation
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Regimes of QCD
Asymptotic freedomDilute, hard scattering
Bulk matter, cold
Deconfined matterBulk matter, hot
Baryon-dense matter (neutron stars)
Bound statesHadrons/hadronic matter
Heavy ion physics
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Accelerators and colliders
• p+p colliders (fixed target+ISR, SPPS, TevaTron, LHC)– Low-density QCD
– Broad set of production mechanisms
• Electron-positron colliders (SLC, LEP)– Electroweak physics
– Clean, exclusive processes
– Measure fragmentation functions
• ep, p accelerators (SLC, SPS, HERA)– Deeply Inelastic Scattering, proton structure
– Parton density functions
• Heavy ion accelerators/colliders (AGS, SPS, RHIC, LHC)– Bulk QCD and Quark Gluon Plasma
Many decisive QCD measurements done
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The first and only ep collider in the world
e± p
27.5 GeV 920 GeV
√s = 318 GeV
Equivalent to fixed target experiment with 50 TeV e±
Loca
ted
in
Ham
bu
rg
H1
Zeus
The HERA Collider
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XpeXepe ee )( :CC , :NC
NC:
CC:
DIS: Measured electron/jet momentum fixes kinematics
Example DIS events
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Proton structure F2
Q2: virtuality of the x = Q2 / 2 p q‘momentum fraction of the struck quark’
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Factorisation in DIS
Integral over x is DGLAP evolution with splitting kernel Pqq
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Parton density distributionLow Q2: valence structure
Valence quarks (p = uud)x ~ 1/3
Soft gluons
Q2 evolution (gluons)
Gluon content of proton risesquickly with Q2
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p+p dijet at Tevatron
Tevatron: p + p at √s = 1.9 TeV
Jets produced with several 100 GeV
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Testing QCD at high energy
small x
large x
x = partonic momentum fraction
Dominant ‘theory’ uncertainty: PDFs
Theory matches data over many orders of magnitude
Universality: PDFs from DIS used to calculate jet-production
Note: can ignore fragmentation effects
CDF, PRD75, 092006
DIS to measure PDFs
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Testing QCD at RHIC with jets
Jets also measured at RHIC
However: signficant uncertainties in energy scale, both ‘theory’ and
experiment
STAR, hep-ex/0608030
NLO pQCD also works at RHIC
RHIC: p+p at √s = 200 GeV(recent run 500 GeV)
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e+e- → qq → jets
Direct measurement of fragmentation functions
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pQCD illustrated
c
chbbaa
abcdba
T
hpp
z
Dcdab
td
dQxfQxfdxdxK
pdyd
d
0
/222
)(ˆ
),(),(
CDF, PRD75, 092006
jet spectrum ~ parton spectrum
nTTT ppdp
dN
ˆ
1
ˆˆ
jet
hadronT
P
pz ,
fragmentation
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Note: difference p+p, e++e-
p+p: steeply falling jet spectrumHadron spectrum convolution of jet spectrum with fragmentation
e+ + e- QCD events: jetshave p=1/2 √sDirectly measure frag function
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Fragmentation function uncertaintiesHirai, Kumano, Nagai, Sudo, PRD75:094009
z=pT,h / 2√s z=pT,h / Ejet
Full uncertainty analysis being pursuedUncertainties increase at small and large z
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Global analysis of FFproton anti-protonpions
De Florian, Sassot, Stratmann, PRD 76:074033, PRD75:114010
... or do a global fit, including p+p dataUniversality still holds
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Heavy quark fragmentation
Light quarks Heavy quarks
Heavy quark fragmentation: leading heavy meson carries large momentum fraction
Less gluon radiation than for light quarks, due to ‘dead cone’
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Dead cone effect
Radiated wave front cannot out-run source quark
Heavy quark: < 1
Result: minimum angle for radiation Mass regulates collinear divergence
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Heavy Quark Fragmentation II
Significant non-perturbative effects seen even
in heavy quark fragmentation
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Factorisation in perturbative QCD
c
chbbaa
abcdba
T
hpp
z
Dcdab
td
dQxfQxfdxdxK
pdyd
d
0
/222
)(ˆ
),(),(
Parton density functionNon-perturbative: distribution of partons in protonExtracted from fits to DIS (ep) data
Matrix elementPerturbative component
Fragmentation functionNon-perturbativeMeasured/extracted from e+e-
Factorisation: non-perturbative parts (long-distance physics) can be factored out in universal distributions (PDF, FF)
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Reminder: parton kinematics
ep DIS:
Know: incoming electron 4-momMeasure: scattered electon 4-momReconstruct: exchanged 4-mommomentum fraction of struck quark
e+e-
Know: incoming electrons 4-momMeasure: scattered quark (jet) directionsReconstruct: exchanged 4-mom = parton momenta
p+p: direct access to underlying kinematics only via • , jet reconstruction• Exclusive measurements (e.g. di-leptons, di-hadrons)
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Differential kinematics in p+pExample: 0-pairs to probe low-x
p+p simulation
hep-ex/0502040
Forward pion
Second pion
Resulting x-range
Need at least two hadrons to fix kinematics in p+p
211
ees
px T
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Direct photon basics
direct
fragment
Gordon and V
ogelsang, PR
D48, 3136
Small Rate: Yields
NLO: quarks radiate photons
LO: does not fragment,direct measure of partonic kinematics
‘fragmentation photons’
Direct and fragmentation contributionsame order of magnitude
37
R
Experimental challenge: 0
Below pT=5 GeV: decays dominant at RHIC
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Direct photons: comparison to theoryP. Aurenche et al, PRD73:094007
Good agreement theory-experiment From low energy (√s=20 GeV at CERN) to highest energies (1.96 TeV TevaTron)
Exception: E706, fixed target FNAL deviates from trend: exp problem?
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(fragment) / (inclusive)
Experimental access to fragmentation • Two Methods in p+p 200GeV
– Isolation cut ( 0.1*E > Econe(R=0.5) ): identifies non-fragmentation photons– Photons associated with high-pT hadron: fragmentation
PHENIX, PRL98, 012002 (2007)
R E Triggering leadinghadron
Look at associatedphotons
(Isolated)/(all direct)
Only ~10% of show significant associated hadronic activity
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Perturbative QCD processes
• Hadron production• Heavy flavours• Jet production
– e+e- → jets – p(bar)+p → jets
• Direct photon production
Measurem
ent difficulty
The
ory
diff
icul
ty
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Summary
• QCD is theory of strong interactions– Fundamental d.o.f quarks and gluons– Ground state: hadrons (bound states)
• Perturbative QCD, asymptotic freedom at high Q2, small distances
• Factorisation for pQCD at hadron colliders:– DIS to measure proton structure– e+ e- to measure fragmentation functions– Calculate jet, hadron spectra at hadron colliders
More on bulk QCD next lecture
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QCD NLO resources
• PHOX family (Aurenche et al)http://wwwlapp.in2p3.fr/lapth/PHOX_FAMILY/main.html
• MC@NLO (Frixione and Webber)http://www.hep.phy.cam.ac.uk/theory/webber/MCatNLO/
You can use these codes yourself to generate the theory curves!
And more: test your ideas on how to measure isolated photons or di-jets or...
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Extra slides
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DIS kinematics
dσ~
2
Lμν Wμν
Ee
E
Ep
q = k – k’, Q2 = -q2
Px = p + q , W2 = (p + q)2
s= (p + k)2
x = Q2 / (2p.q)
y = (p.q)/(p.k)
W2 = Q2 (1/x – 1)
Q2 = s x y
s = 4 Ee Ep
Q2 = 4 Ee E’ sin2θe/2y = (1 – E’/Ee cos2θe/2)x = Q2/sy
The kinematic variables are measurable
Leptonic tensor - calculable
Hadronic tensor- constrained by
Lorentz invariance
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DIS kinematics
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QCD and quark parton model
S. Bethke, J Phys G 26, R27
Running coupling:s grows with decreasing Q2
Asy
mpt
otic
free
dom
At low energies, quarks are confined in hadrons
Confinement, asymptotic freedom are unique to QCD
At high energies, quarks and gluons are manifest
gqqee
Theory only cleanly describes certaint limits
Study ‘emergent phenomena’ in QCD
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Resolved kinematics inDeep Inelastic Scattering
small x
large x
x = partonic momentum fraction
DIS: Measured electron momentum fixes kinematics
),(2
),(2
14 2
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2
2
4
2
2
2
QxFy
QxFy
yxQdxdQ
dL
eXep