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Parton distributions at 14 TeV with ATLAS

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Title: Electroweak physics at the LHC with ATLAS Author: Moraes Last modified by: Moraes Created Date: 3/11/2003 7:52:30 PM Document presentation format – PowerPoint PPT presentation

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Title: Parton distributions at 14 TeV with ATLAS


1
Parton distributions at 14 TeV with ATLAS
  • Arthur M. Moraes
  • University of Sheffield, UK
  • (on behalf of the ATLAS collaboration)

QCD 2003
Montpellier, 2nd 9th July 2003
2
Outline
  • LHC and ATLAS.
  • Precision tests measurements in unexplored
    kinematic region.
  • Jet physics.
  • Direct photon production ( fg(x), parton dynamics
    ).
  • Drell-Yan and W/Z production.
  • Heavy quark production.
  • Conclusions.

A. M. Moraes
3
LHC (Large Hadron Collider)
p-p collisions at vs 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)

Process s (nb) Events/year (L 10 fb-1)
Inclusive bb 5 x 105 1013
Inclusive jet pT gt 200 GeV 100 1010
Inclusive tt 0.8 107
Inclusive jet ET gt 2 TeV 10-8 103
large statistics small statistical error!
-
Production cross section and dynamics are largely
controlled by QCD.
-
Mass reach (ET) up to 5 TeV
Test QCD predictions and perform precision
measurements.
A. M. Moraes
4
ATLAS A Toroidal LHC AparatuS
7,000 tons
Multi-purpose detector coverage up to ?
5 design to operate at L 1034cm-2s-1
Inner Detector (tracker) Si pixel strip
detectors TRT 2 T magnetic field coverage up
to ?lt 2.5.
22m
  • Calorimetry
  • highly granular LAr EM calorimeter
  • ( ? lt 3.2)
  • hadron calorimeter scintillator tile
  • ( ? lt 4.9).

44m
Jet energy scale precision of 1 ( W ? jj Z (
ll) jets)
  • Muon Spectrometer
  • air-core toroid system
  • ( ? lt 2.7).

Absolute luminosity precision 5 ( machine,
optical theorem, rate of known processes)
Most of the QCD related measurements are expected
to be performed during the low-luminosity
stage.
Likely to limit cross-section measurements.
5
LHC Parton Kinematics
  • Essentially all physics at LHC are connected to
    the interactions of quarks and gluons (small
    large transferred momentum).
  • This requires a solid understanding of QCD.
  • Accurate measurements of SM cross sections and
    QCD related processes at the LHC will further
    constrain the pdfs.
  • The kinematic acceptance of the LHC detectors
    allows a large range of x and Q2 to be probed
    ( ATLAS coverage ? lt 5 ).

6
Jet physics
? 0 lt ? lt 1 ? 1 lt ? lt 2 2 lt ? lt 3
  • Test of pQCD in an energy regime never probed!

ds/dET nb/GeV
( probing the smallest distance scales at the LHC
? huge cross-section!)
  • The measurement of the jet production
    cross-section is sensitive both to the quark and
    gluon densities.
  • The measurement of di-jets and their properties
    (ET and ?1,2) can be used to constrain p.d.f.s.

ET Jet GeV
L 300 fb-1
  • reconstruct x1,2 Q2 of the hard scattering
    (LO)

Q2 GeV2
LHC - ATLAS
  • Systematic errors jet algorithm, calorimeter
    response (jet energy scale), jet trigger
    efficiency, luminosity (dominant uncertainty 5
    -10 ), the underlying event.

105 lt Q2 lt 106 GeV2
0.01 lt x lt 0.6
  • more studies are needed to quantify
    uncertainties
  • combined channels have also to be investigated!
  • At the LHC the statistical uncertainties on the
    jet cross-section will be small.

ET gt 180 GeV and ? lt 3.2
7
Direct photon production
?? gt 2.5
  • direct production of photons information on
    gluon density in the proton, fg(x).

( requires good knowledge of as)
Production mechanism
qg??q
dominant (QCD Compton scattering)
-
qq??g
Background mainly related to fragmentation
(non-perturbative QCD)
Isolation cut reduces background from
fragmentation (p0)
( cone isolation)
ATLAS high granularity calorimeters ( ? lt 3.2
) allow good background rejection.
LHC
HERA
pT? gt 40 GeV ? Q2 gt 103 GeV2
Q2 gt 103 GeV2
x gt 0.01
(statistics)
5. 10-4 lt x lt 0.2
?
8
Drell-Yan processes
( e, µ channels! )
  • W and Z production at the LHC huge statistical
    samples clean experimental channel.

W and Z production 105 events containing W
(pTW gt 400 GeV) for L 30fb-1 104 events
containing Z (pTZ gt 400 GeV) for L 30fb-1
LHC
HERA
Q2 6 (8) 103 GeV2
Q2 gt 104 GeV2
( ? gt 2.5 )
3 10-4 lt x lt 0.1
W ? l?
x gt 0.1
BR x ds/dy (pb)
W- ? l- ?
DY production of muon pairs
mµµ gt 400 GeV 104 events for L 30fb-1
Q2 gt 1.6 105 GeV2
2.3 10-3 lt x lt 0.34
( ? gt 2.5 )
  • W and W- production different yW distributions

(differences in parton distributions leading to W
production u and d)
  • It can be used to constrain quark and anti-quark
    densities in the proton.

9
Determination of sin2?efflept(MZ2 )
  • sin2?efflept is one of the fundamental
    parameters of the SM (constrain the Higgs mass
    and check consistency of the SM) !

  • Main systematic effect uncertainty on the
    p.d.f.s, lepton acceptance (0.1), radiative
    correction calculations.
  • sin2?efflept will be determined at the LHC by
    measuring AFB in dilepton production near the Z
    pole.

AFB b a - sin2?efflept( MZ2 )
a and b calculated to NLO in QED and QCD.
y cuts ee- ( y(Z) gt 1 ) ?AFB ?sin2?efflept
y( l1,2 ) lt 2.5 3.03 x 10-4 4.0 x 10-4
y( l1 ) lt 2.5 y( l2 ) lt 4.9 2.29 x 10-4 1.41 x 10-4
s ( Z ? l l - ) 1.5 nb (for either e or µ)
( statistical )
( statistical )
sin2?efflept( MZ2 ) 0.23126 1.7 x 10-4
(global fit PDG)
Can be further improved combine
channels/experiments.
L 100 fb-1
10
Heavy flavour production
Process s (nb) Events/year (L 10 fb-1)
bb 5 x 105 1012
tt 0.8 107
-
-
  • The dominant production mechanism for heavy
    quarks (b and t) at the LHC is gluon-gluon
    interaction.

LHC Heavy quarks factory!
  • Measurements of heavy quark production will
    provide constraints on the gluon density.

c and b quarks
  • c and b can be measured by quark flavour tagged
    sub-sample of photon-jet final states
  • dominant production c(b) g ? c(b) ?
  • jet flavour is identified as a c or b jet by
    using inclusive high-pT muons b tagging

muon spectrum of selected events
pT? gt 40 GeV
0.001 lt xc (xb)lt 0.1
pTµ 5 - 10 GeV
(L 10 fb-1)
11
Conclusions
  • LHC will probe QCD to unexplored kinematic
    limits
  • Jet studies (test of pQCD, constrain p.d.f.s,
    physics studies)
  • Prompt-photon production will lead to improved
    knowledge of fg(x) and parton dynamics
  • Drell-Yan processes will provide information that
    can be used to constrain quark and anti-quark
    densities (W and Z decays, muon pairs, W and W-
    production)
  • Heavy quark production (provide constraints for
    the gluon density c and b densities).
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