UnderlyingEvent in Top Quark Pair Production · Distribution of all particle flow candidates...
Transcript of UnderlyingEvent in Top Quark Pair Production · Distribution of all particle flow candidates...
Underlying Event in Top Quark Pair Production
(based on arXiv:1807.02810/CMS-TOP-17-015)
Jianguo Bian and Efe YazganIHEP, CAS
4th China LHC Physics Workshop19-22 December 2018
Central China Normal University, Wuhan
Top Quark and QCD• Top quark measurements
• Test and understand QCD effects à ultimate precision in top quark mass, its interpretation and in other properties.
• Beyond standard model effects. • Top quark pair cross section measurements better than NNLO+NNLL
precision. • Top quark measurements precision ~0.3-0.4% with dominant uncertainties
• Hadronization• Modeling of hard scattering (parton shower – matrix element matching, top quark
pT, PDF)• Jet energy calibration and pile-up • Underlying event
Some theory uncertainties (hadronization, top pT, underlying event, …) may be decreased.
Goal/expectation for HL-LHC Direct top mass measurements < 0.1% precision.
How to Decrease Uncertainties
• Test matrix element + parton shower configurations and tunes using well-defined differential measurements. • Detailed studies of each source of modelling
uncertainty. • Measurements (e.g. top mass) in different
phase-space regions. • …
In this talk, we present a dedicated underlying event measurement in ttbar events to test the tune used in top quark measurements and to test some commonly used event generator configurations.
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Underlying event/Multi-parton interactions:Here, defined as the charged particle activity that can’t be attributed to the hard process: à select charged particles that are not associated to the leptons, b jets or pile-up.
Hard process
Fragmentation/Parton shower
decay (of unstableparticles).
Hadronization
Beam remnants
Event Selection
In this case, the hard process is ttbar.
In this case, Final state from the hard process: dilepton, ≥ 2 bjets,
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for the main analysis
e±e⌥, µ±µ⌥<latexit sha1_base64="/9E6s1qSBQNJtJ2tk8Xpr2nhxN0=">AAAC4XicjVHLSsNAFD2Nr1pfUZe6CBbBhZRUBF0W3bisYB/Q1pJMpzU0jyGZCKW4cedO3PoDbvVnxD/Qv/DOGEEtohMyc+bce87MnesK30ukbb/kjKnpmdm5/HxhYXFpecVcXasnURozXmORH8VN10m474W8Jj3p86aIuRO4Pm+4w2MVb1zyOPGi8EyOBO8EziD0+h5zJFFdc5Oft0Vg0RyIXasdpHqr10B0zaJdsvWwJkE5A0VkoxqZz2ijhwgMKQJwhJCEfThI6GuhDBuCuA7GxMWEPB3nuEKBtCllccpwiB3SPKBdK2ND2ivPRKsZneLTH5PSwjZpIsqLCavTLB1PtbNif/Mea091txGtbuYVECtxQexfus/M/+pULRJ9HOoaPKpJaEZVxzKXVL+Kurn1pSpJDoI4hXsUjwkzrfx8Z0trEl27eltHx191pmLVnmW5Kd7ULanB5Z/tnAT1vVKZ8Ol+sXKUtTqPDWxhh/p5gApOUEWNvK/xgEc8Gcy4MW6Nu49UI5dp1vFtGPfvlZiacg==</latexit><latexit sha1_base64="/9E6s1qSBQNJtJ2tk8Xpr2nhxN0=">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</latexit><latexit sha1_base64="/9E6s1qSBQNJtJ2tk8Xpr2nhxN0=">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</latexit><latexit sha1_base64="/9E6s1qSBQNJtJ2tk8Xpr2nhxN0=">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</latexit>
For the normalization of the Drell-Yan background.
(all other backgrounds from simulation)
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Underlying event/Multi-parton interactions:à Contribution from both pileup and hard process identified and excluded.à Track associated to the charged particle flow
candidate is required to be compatible with the primary vertex è reduces the pileup contamination in the charged particle collection to negligible amounts +
à All charged particle candidates with pT>900 MeV and |eta|<2.1 are selectedà If a charged particle is clustered in a jet or
if it matches to a hard lepton from ttbar, it is removed from the collection of underlying event particles.
Hard process
Fragmentation/Parton shower
decay (of unstableparticles).
Hadronization
Beam remnants
Event Selection
Underlying Event in ttbar
Distribution of all particle flow candidates reconstructedin a Powheg + Pythia8 simulated ttbar event.
Big filled red circles = leptons from ttbar.Big filled orange circles = charged particles clustered in b-jet from ttbar.
For all particles pT> 900 MEV
à Using clean dilepton state makes it easy to isolate the underlying event from the products of the hard scattering .
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CMSSimulation tt̄ ! (e⌫b)(µ⌫b) (13 TeV)
NeutralPU charged
ChargedCharged from b
Lepton
Underlying Event in ttbar Events• Properties of the underlying event is studied for the first time at a scale of
> 2mt (i.e. > ~340 GeV)• > 200 distributions investigated. • Measurements unfolded to particle level:
Defined using the sphericity tensor
Underlying Event in ttbar Events
• Unfolded UE data in ttbar compared to Powheg+Pythia8• ~20 charged particles with
• à vectorially summing to ~10 GeV recoil. • Sensitive to
• Parton shower Initial State Radiation (ISR) and Final State Radiation (FSR)
• Underlying event tune fit (UE up and down)
chN0 20 40 60 80 100 120
)ch
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(13 TeV)-135.9 fb
pT ⇠ pZ ⇡ 2GeV<latexit sha1_base64="FEBPQBv2S/iPWfj/vK6+6vtwq9s=">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</latexit><latexit sha1_base64="FEBPQBv2S/iPWfj/vK6+6vtwq9s=">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</latexit><latexit sha1_base64="FEBPQBv2S/iPWfj/vK6+6vtwq9s=">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</latexit><latexit sha1_base64="FEBPQBv2S/iPWfj/vK6+6vtwq9s=">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</latexit>
Underlying Event in ttbar Events
• Color reconnection models
Theo
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chN0 20 40 60 80 100 120Th
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MG5_aMC
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• Parton shower Initial State Radiation (ISR) and Final State Radiation (FSR)
• Underlying event tune fit (UE up and down)
• Different matrix element generators and partonshower codes.
Underlying Event in ttbar Events
• Aplanarity peaks at ~0.1 à UE events are close to planar.• MPI is essential. • Color reconnection effect is subtle. • Using MG5_aMC+Pythia8 or Powheg+Pythia8 doesn’t make significant difference.
• These are the two main codes used in top quark simulation in CMS.
• Sherpa, and Herwig++/7 need dedicated tuning.
A0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5
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eory
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Underlying Event in ttbar Events• Further categorize events using the dilepton transverse momentum, mass and
number of jets. • High correlated to reconstructed top kinematics: pT(ttbar), m(ttbar) and ISR but easier to measure
than reconstrued top kinematics. • Dilepton direction is also used to define standard underlying event regions (towards, away,
transverse).
toward, ~pT (``)
transverse
transverse
awayaway
CMS preliminary simulation (13 TeV)tt̄ ! (e⌫b)(µ⌫b)
chargedlepton (pT/2) Category
Inc. =0 =1 2³ Inc. =0 =1 2³ Inc. =0 =1 2³
[GeV
]ñ Tp á
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Data PW+PY8ISR up ISR downFSR up FSR downUE up UE down
Toward Transverse Away
CMS (13 TeV)-135.9 fb
Underlying Event in ttbar Events• Further categorize events using the dilepton transverse momentum, mass and
number of jets. • High correlated to reconstructed top kinematics: pT(ttbar), m(ttbar) and ISR but easier to measure
than reconstrued top kinematics. • Dilepton direction is al used to define standard underlying event regions (towards, away,
transverse).
toward, ~pT (``)
transverse
transverse
awayaway
CMS preliminary simulation (13 TeV)tt̄ ! (e⌫b)(µ⌫b)
chargedlepton (pT/2)
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PW+PY8ISR upISR downFSR upFSR downUE upUE down
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no MPIno CRQCD basedGluon moveERD onRopeRope (no CR)
Category
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MG5_aMCPW+HW++PW+HW7
Toward Transverse Away
• Observables/categories enhance sensitivity to the modeling of MPI, color reconnection, and αs
FSR(MZ) in Pythia8. • Among the parameters with the largest impact on the ttbar modeling.• Data disfavor default settings in HERWIG++, HERWIG7, and SHERPA à Need tuning.• Choice of NLO ME generator (Powheg or MG5_aMC@NLO[FxFx] + Pythia8) does not impact the UE
in ttbar.
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Underlying Event in ttbar Events
Category
Inc. =0 =1 2³ [0,20[[20,40[
[40,80[[80,120[
>120 [0,60[[60,120[
[120,200[>200
[GeV
]ñ zpS á
50
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Extra jets (ll) [GeV]T
p m(ll) [GeV]
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PW+PY8ISR upISR downFSR upFSR downUE upUE down
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no MPIno CRQCD basedGluon moveERD onRopeRope (no CR)
Category
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[40,80[[80,120[
>120 [0,60[[60,120[
[120,200[>200
Dat
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4-2-024 Sherpa
MG5_aMCPW+HW++PW+HW7
Extra jets (ll) [GeV]T
p m(ll) [GeV]
Underlying Event in ttbar EventsSource % Uncertainty
Nch  pT  pz pT pz |~pT| S A C DStatistical 0.1 0.2 0.3 0.2 0.2 0.3 0.1 0.1 0.1 0.1
Experimental
Background 1.2 1.6 1.8 0.4 0.7 1.6 0.4 0.7 0.3 0.7Tracking eff. 4.4 4.2 4.9 0.8 0.4 4.0 0.4 0.6 0.2 0.6
Theory
µR/µF 0.5 0.8 1.0 0.3 0.3 1.0 0.1 0.1 0.1 0.2Resummation scale 0.2 0.8 0.5 1.1 0.2 1.6 0.8 0.4 0.2 0.7aFSR
S (MZ) 0.5 0.7 0.7 0.8 1.7 0.7 0.2 1.0 0.2 1.2aISR
S (MZ) 0.1 0.3 1.1 1.2 0.7 0.4 0.2 0.5 0.1 1.3UE model 0.1 0.1 0.2 1.0 0.4 0.5 0.2 0.2 0.1 0.9mt 0.4 0.7 1.5 0.6 0.9 0.5 0.1 0.1 0.1 0.7pT(t) 1.4 4.4 4.5 2.8 2.1 6.7 0.2 0.5 0.2 0.3
Total 4.9 6.5 7.3 3.7 3.1 8.2 1.1 1.6 0.6 2.4
• The measurements of the normalized differential cross sections are dominated by systematic uncertainties although the statistical uncertainty is also a large component in some cases.
• Experimental uncertainties à most relevant is the tracking efficiency.• Theory uncertainties have in general more effect à better tuning of the model parameters needed.
Uncertainties affecting the measurement of the average of the UE observables. The values are expressed in % and the last row reports the quadratic sum of the individual contributions.
Underlying Event in ttbar Events
• Test the universality of the UE hypothesis to scales up to 2mtthan the ones UE models are usually tuned.• Measurements in categories of
m(ll) indicate that it should be validat even higher scales.
15
§ The measurements will be used to improve the assessment of systematic uncertainties in future measurements. A first example is given next.
Category
Inc. =0 =1 2³ [0,20[[20,40[
[40,80[[80,120[
>120 [0,60[[60,120[
[120,200[>200
ñ ch
Ná
10
20
30
40
50
60Data PW+PY8ISR up ISR downFSR up FSR downUE up UE down
Extra jets (ll) [GeV]T
p m(ll) [GeV]
CMS (13 TeV)-135.9 fb
Underlying Event in ttbar Events
16
Uncertainties correspond to a ~√2 variation of µR (instead of a ~2 variation).
We have the data to make similar dedicated studies to control modeling in many differentprocesses and in different phase-space regions.
• Data prefer lower αsFSR(MZ) than
assumed in Monash.• Similar result from jet substructure in ttbar
events [CMS-PAS-TOP-17-013: https://arxiv.org/abs/1808.07340 ]
0.08 0.09 0.1 0.11 0.12 0.13 0.14 0.15 0.16)
Z(MFSR
Sa
0
5
10
15
20
25
30
35
40
45
502 c Inclusive
Away
Toward
Transverse
CMS (13 TeV)-135.9 fb
Summary• First ever measurement of the underlyinf activity in ttbar events.
• Measurements are expected to be valid for other ttbar final states and can be used as reference for complementary studies• Color reconnection models, e.g. in the description of Wàqq decays.
• The choice of observables and categories are made to enhance the sensitivity to modelling of multi-parton interactions (MPI), color reconnection and the strong coupling parameter in the PYTHIA8 parton shower.
• Most of the distributions studied indicate a fair agreement between the data and the POWHEG+PYTHIA8 with the CUETP8M2T4 tune, but disfavour the setups in which MPI or CR are switched off of that use a higher value for the strong coupling for FSR.
• Data also disfavour the default configurations in HERWIG++, HERWIG7 or SHERPA.
• It has been also verified that the choice of the next-to-leading order matrix-element generator does not impact the expected characteristics of the UE.
Summary• The results test the hypothesis of universality of underlying event at an energy scale
typically higher than the ones at which these models have been studied.
• The UE model is tested up to a scale of 2 x m(top) and the measurements in ctaegories of diplepton invariant mass indicate that it should be valid even at higher scales.
• The measurements can be used to improve the assessment of systematics uncertainties in future top quark measurements.
• The results show that a value of αs(FSR)= 0.120 +/- 0.006 is consistent with the data (and the world average value).
• The corresponding uncertainties translate to a variation of the renormalization scale by a factor of √2.