qcd at lhc with atlas · a. m. moraes qcd physics at atlas aps april 5, 2003 outline lhc and atlas....
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QCD at LHC with ATLAS
Arthur M. Moraes
University of Sheffield, UK(on behalf of the ATLAS collaboration)
APS April 2003 Meeting – Philadelphia, PA
APS April 5, 2003QCD physics at ATLASA. M. Moraes APS April 5, 2003QCD physics at ATLASA. M. Moraes
OutlineLHC and ATLAS.
Precision tests & measurements in unexplored kinematic region.
Jet physics.
Parton luminosities and p.d.f.’s ( high-Q2 processes at LHC: parton-parton collider ).
Direct photon production ( fg(x), background to H → γγ, parton dynamics ).
Measurement of the αS at very large scales.
Background processes: multi-parton interaction, minimum-bias and the underlying event.
Conclusion.
APS April 5, 2003QCD physics at ATLASA. M. Moraes
LHC (Large Hadron Collider):
• p-p collisions at √s = 14TeV
• bunch crossing every 25 ns (40 MHz)
low-luminosity: L ≈ 2 x 1033cm-2s-1
(L ≈ 20 fb-1/year)
high-luminosity: L ≈ 1034cm-2s-1
(L ≈ 100 fb-1/year)
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Mass reach up to ~ 5 TeV
~ 1010100Inclusive jetpT > 200 GeV
~ 1070.8Inclusive tt
~ 103~10-8Inclusive jetET > 2 TeV
~ 10135 x 105Inclusive bb
Events/year (L = 10 fb-1)
σ (nb)Process
Test QCD predictions and perform precision measurements.
Production cross section and dynamics are largely controlled by QCD.
-
-
large statistics: small statistical error!
APS April 5, 2003QCD physics at ATLASA. M. Moraes
ATLAS: A Toroidal LHC AparatuS
~44m
~22m
7,000 tons• Multi-purpose detectorcoverage up to |η| = 5;design to operate at L= 1034cm-2s-1
Most of the QCD related measurements are expected to be performed during the “low-luminosity” stage.
• Inner Detector (tracker)Si pixel & strip detectors + TRT;2 T magnetic field;coverage up to |η|< 2.5.
• Calorimetryhighly granular LAr EM calorimeter( | η |< 3.2);hadron calorimeter – scintillator tile( | η |< 4.9).
• Muon Spectrometerair-core toroid system(| η | < 2.7).
Jet energy scale: precision of 1% ( W → jj; Z ( ll) + jets)
Absolute luminosity: precision ≤ 5% ( machine, optical theorem, rate of known processes)
APS April 5, 2003QCD physics at ATLASA. M. Moraes
LHC Parton Kinematics
10-7 10-6 10-5 10-4 10-3 10-2 10-1 100100
101
102
103
104
105
106
107
108
109
fixedtarget
HERA
x1,2 = (M/14 TeV) exp(±y)
Q = M
M = 10 GeV
M = 100 GeV
M = 1 TeV
M = 10 TeV
66y = 40 224
Q2
(GeV
2 )x
Essentially all physics at LHC are connected to the interactions of quarks and gluons (small & large transferred momentum).
Accurate measurements of SM cross sections at the LHC will further constrain the pdf’s.
The kinematic acceptance of the LHC detectors allows a large range of x and Q2 to be probed ( LHC coverage: |y| < 5 ).
This requires a solid understanding of QCD.
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Jet physics• Test of pQCD in an energy regime never probed!
40> 3 TeV3 x 103> 2 TeV4 x 105> 1 TeVNeventsJet ET
0 < |η| < 1
1 < |η| < 2
2 < |η| < 3
ET Jet [GeV]
dσ/d
ET [n
b/G
eV] NLO QCD
10-11
10-9
10-7
10-5
10-3
10-1
1
0 1000 2000 3000 4000 5000
At the LHC the statistical uncertainties on the jet cross-section will be small.
• Systematic errors:jet algorithm,calorimeter response (jet energy scale),jet trigger efficiency,luminosity (dominant uncertainty 5% -10% ),the underlying event.
• The measurement of di-jets and their properties (ET and η1,2) can be used to constrain p.d.f.’s.
• Multi-jet production is important for several physics studies: a) tt production with hadronic final statesb) Higgs production in association with tt and bb c) Search for R-parity violating SUSY (8 – 12 jets).
- --
• Inclusive jet cross section: αS(MZ) measurement with 10% accuracy.( can be reduced by using the 3-jet to 2-jet production )
10 5
10 6
10 7
10 8
0 1 2 3
log(1/x)
Q2 [G
eV2 ]
L = 30 fb-1
● 0 < |η| < 1○ 1 < |η| < 2■ 2 < |η| < 3
dσ/d
ET
[nb/
GeV
]
ET Jet [GeV]
Q2
[GeV
2 ]
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Measuring parton luminosities and p.d.f.’s
Uncertainties in p-p luminosity (±5%) and p.d.f.’s(±5%) will limit measurement uncertainties to ±5% (at best). • Using only relative cross section measurements,
might lead eventually to accuracies of ±1%.
),,(),,()( 221 XgqqQxxpdfLXppN theoryppevents →××=→ − σ
quark flavour tagged γ-jet final states;use inclusive high-pT μ and b-jet identification
(lifetime tagging) for c and b;use μ to tag c-jets;5-10% uncertainty for x-range: 0.0005 – 0.2
γc, γb, sg→Wc
γ-jet studies: γ pT > 40 GeVx-range: 0.0005 – 0.2γ-jet events: γ pT ~ 10-20 GeVlow-x: ~ 0.0001±1%
precise measurements of mass and couplings;huge cross-sections (~nb);small background.x-range: 0.0003 – 0.1± 1%
γ-jet, Z-jet, W±-jet
(high-Q2 reactions involving gluons)
W± and Z leptonicdecays
(high-mass DY lepton pairs and other processes dominated by qq )-
(u,d)
• For high Q2 processes LHC should be considered as a parton-parton collider instead of a p-p collider.
qq-
g
s, c, b
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Understanding photon production:Higgs signals (H→γγ) & background;prompt-photon can be used to study the underlying
parton dynamics;gluon density in the proton, fg(x)
ATLAS: high granularity calorimeters ( |η| < 3.2 ) allow good background rejection.
Isolation cut: reduces background from fragmentation (π0)
qg→γqqq→γg-
Production mechanism:dominant (QCD Compton scattering)
10-7
10-6
10-5
10-4
10-3
10-2
10-1
1
200 400 600 800 1000
| ηγ | < 2.5
pTγ (GeV)
dσ/d
p T (
nb/G
eV)
pTγ > 40 GeV
Direct photon production
0
0.25
0.5
0.75
1
0 0.5 1 1.5 2
|η|E
ffic
ienc
y
All γ,sUnconverted γ,sConverted γ,s
Low luminosity run: the photon efficiency is more than 80% ( LArcalorimeter ).
Background: mainly related to fragmentation ( non-perturbativeQCD)
( requires good knowledge of αs)
( cone isolation)
|η|
APS April 5, 2003QCD physics at ATLASA. M. Moraes
• However, measurements of αS(MZ) will not be able to compete with precision measurements from e+e- and DIS (gluon distribution).
• Differential cross-section for inclusive jet production (NLO )ECM = 14 TeV, -1.5 < ηjet < 1.5
• A and B are calculated at NLO with input p.d.f.’s.
• Fitting this expression to the measured inclusive cross-section gives for each ET bin a value of αS(ET).
• Systematic uncertainties:p.d.f. set ( ±3%),parametrization of A and B,renormalization and factorization scale
( ±7%).
( ) ( ) ( ) ( )TRSTRST
EBEAdEd μαμασ 32~ +
• Verification of the running of αS : check of QCD at the smallest distance scales yet uncovered:
αS= 0.118 at 100 GeVαS~ 0.082 at 4 TeV
Determination of αs: scale dependence
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Multiple parton interactions (MPI)p p
Aσ^
σ^B
• AFS, UA2 and more recently (and crucially!) CDF, have measured double parton interactions.
σeff = 14.5 ± 1.7 mb
σeff has a geometrical origin;parton correlation on the transverse space;it is energy and cut-off independent.
( )eff
BAcutTD mp
σσσσ
2=
• σD decreases as pT→∞ and grows as pT→ 0.• σD increases faster with s as compared to σS.
Multiple parton collisions are enhanced at the LHC!
4-jet production: 2 → 4 v (2 → 2)2
• Source of background:WH+X→ (lν) bb+X,Zbb→ (lν) bb+X,W + jets, Wb + jets and Wbb + jets,tt → llbb,final states with many jets pT
min ~ 20 – 30 GeV.
-- -
- --
2 → 4
(2 → 2)2
b
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Minimum-bias and the underlying eventMinimum bias events
Experimental definition: depends on the experiment trigger! “Minimum bias” is usually associated to non-single diffractive events(NSD), e.g. ISR, UA5, E735, CDF.
difndifddifselastot ... σσσσσ +++=
σn.dif ~ 55 - 65mbσtot ~ 102 - 118 mb
Underlying event in charged jet evolution (CDF style analysis)
It is not only minimum bias event!
Δφ = φ − φljet
In a hard scattering process, the underlying event has a hard component (initial + final-state radiation and particles from the outgoing hard scattered partons) and a soft component (beam-beam remnants).
Best described with MPI models!
(PYTHIA) (PHOJET) (PYTHIA) (PHOJET)
APS April 5, 2003QCD physics at ATLASA. M. Moraes
Conclusions:LHC will probe QCD to unexplored kinematic limits;
Jet studies (test of pQCD, constrain p.d.f.’s, physics studies);
Luminosity uncertainties can be reduced by measurements of relative luminosities: high-Q2 and wide x-range;
Prompt-photon production will lead to improved knowledge of background levels (H→γγ), fg(x) and parton dynamics;
αs at high-energy scales (test of the running of αs);
Multiple parton scattering: source of background and/or new physics channels;
Minimum-bias and the underlying event: improved understanding of events dominated by soft processes.