1 hadronic event shape variables in pp collision at 7 tev introduction data-set and event selection...
TRANSCRIPT
1
Hadronic Event Shape Variables in pp collision at 7 TeV
• Introduction
• Data-set and Event Selection
• Comparison of Basic Jet Objects in Data and MC
• Event Shape Variables in Data and MC
• Systematics and Sensitivity
• Final Results
• Summary
PAS : QCD-10-013, CMS AN-2010/100 and CMS AN-2010/127
2
Introduction
Variables are defined in terms of four momenta in the transverse plane, in analogy to e+e− collider, Banfi, Salam, Zanderighi, JHEP 0408 (2004) 62
Central Transverse Thrust
Central Thrust Minor
• Experiment : Normalised Event Shape variables are expected to be robust against jet energy scale uncertainties and jet energy resolution effects
• Theory : Calculations of Event Shape variables are carried out in perturbative QCD
• Event Shape variables can be used to distinguish different models of QCD multijet production
• Possibility with large statistics: measurement of αs
3
Central Transverse Thrust• Plotted in the natural logarithm, log τ = log(1−T)
4
MC samples• /MinBias/Spring10-START3X V26A 357ReReco-v2/GEN-SIM-RECO
• /MinBias TuneD6T 7TeV-pythia6/Spring10-START3X V26B-v1/GEN-SIM-RECO
• /MinBias TuneP0 7TeV-pythia6/Spring10-START3X V26B-v1/GEN-SIM-RECO
• /MinBias 7TeV-pythia8/Spring10-START3X V26B-v1/GEN-SIM-RECO
• /QCD Ptxx/Summer10-START36 V9 S09-v1/GEN-SIM-RECODEBUG, where range of pˆT from15 GeV/c to kinematic limit (D6T sample, default MC).
• /QCD Ptyy-herwig/Summer10-START36 V9 S09-v1/GEN-SIM-RECO, where range of pˆT from15 GeV/c to kinematic limit.
• /QCD Pt-yytozz 7TeV-pythia8/Summer10-START36 V10 S09-v1/GEN-SIM-RECO, where yytozz are the range of pˆT from 15 GeV/c to kinematic limit.
• /QCDxxJets Ptyytozz-alpgen/Summer10-START36 V9 S09-v1/GEN-SIM-RECO, where xx = 2,3,4 and 5, yytozz are the range of pˆT ranges from 40 GeV/c to kinematics limit.
• /QCD Ptyytozz-madgraph/Summer10-START36 V9 S09-v1/GEN-SIM-RECO, where yytozz are the range of pˆT from 50 GeV/c to 500 GeV/c.
• CMSSW_3_6_1 and Spring10 jet corrections
5
Data and MC event samples• Data :
• 1. /MinimumBias/Commissioning10-SD JetMETTau-Jun14thSkim v1/RECO (run# 134630 to 135802)
• 2. /JetMETTau/Run2010A-Jun14thReReco v2/RECO ( 135821 to 137028)
• 3. /JetMETTau/Run2010A-PromptReco-v4/RECO (run# 137437-139790)
• 4. /JetMETTauMonitor/Run2010A-PromptReco-v4/RECO (run# 137437-139790)
• 5. /JetMETTau/Run2010A-Jul16thReReco-v1/RECO (run# 139779 to 140160)
• Cert 132440-137028 7TeV June14thReReco Collisions10 JSON v2.txt,
• Cert 132440-139790 7TeV StreamExpress Collisions10 JSON.txt
• and Cert 139779-1340159 7TeV July16thReReco Collisions10 JSON.txt
• Dataset Luminiosty (nb−1)• Total HLT Jet30U HLT Jet15U• Run2010A-Jun14thReReco v2 4.92 4.92 4.92• SD JetMETTau-Jun14thSkim 6.64 6.64 6.64• Run2010A-PromptReco-v4 65.53 65.53 4.71• Run2010A-Jul16thReReco-v1 124.98 36.60 2.99• Upto Run 139790 77.09 77.10 16.26• Upto Run 140159 202.07 113.70 19.25
6
Event selection• Technical trigger : LHC clock (BPTX) and veto on Beam Halo !(36||
37||38||39)
• High Level : HLT_Jet15 / HLT_Jet30
• Vertex: at least one primary vertex with |Δz|<15cm, |Δr|<2cm and ndf >4
• Scraping event : less than ten tracks or more than 25% of the tracks with HighPurity
• Jet Cleaning (next slide)
7
Jet algorithms (AntiKt-5)• CaloJet
• PFJet
• JetTPT
• Tracker Jet Selection of Jets : (JTF recommendation)
Used all four types of jets
• Jet selection : Loose JetId cuts for CaloJet and JetJPT ( n90hits>1, emEnergyFraction>0.01, fHPD<0.98)
• PF jet : NeutralEM(Had)EnergyFraction<1.0
– In barrel (|η|<2.4), ChargedHadronEnergyFraction >0, chargedEMEnergyFraction<1.0, charge multiplicity>0
• For all types : At least two objects in jet
• Out of all jets with |η|<2.6, two leading jets should be within |η|<1.3
• Leading two jets should pass JetID criteria and PT1 > 90 GeV/c / 60GeV/c
• Event shapes are calculated with all jets within |η|<1.3 and Pt >30 GeV/c
8
Trigger criteria
• JetMETTauMonitor_Run2010a_May27thRereco
• No matching of Reco and HLT jet, requires one HLT_Jet15 object
• In analysis, Pt of leading jet is > 60 GeV/c also analysis with >90 GeV/c
• Correction for trigger efficiency in Tracker jet
Data
|η|<2.6
9
Event Shape variables (Prel)
10
Comparison of Basic objects : ΔΦ of leading Jets
• With |η|<1.3 MC is normalised to total numbers of entries in data
• Obviously Alpgen and Pythia8 have bias
TrackerJetPFJet
JetJPT
CaloJet
11
Discrepancy in Alpgen sample• Mangano : Alpgen should not looks that different
• CMS collegues : Alpgen and Madgraph should be similar
• Wrong matching efficiency values on production twiki, which have been corrected now. Thanks to the Generator group (esp. Fabian Stoeckli) for the quick response.
sample Old effi New effi2j_40_120 0.64 0.5712j_120_280 0.25 0.2792j_280_500 0.24 0.2042j_500_5000 0.23 0.1923j_40_120 0.17 0.2993j_120_280 0.21 0.2073j_280_500 0.20 0.1443j_500_5000 0.17 0.134
Ratio of cross-sections after matching changed for lowest 3j/2j_Pt40-120 –samplefrom previously 0.18 to now 0.35 due to new evaluated efficienciesSimilarly gamma+1-4jet sample also had wrong weight factor (physics-validation/775.html)
Nobody has noticed this in last six months !!!!!!!!!!!!
12
Comparison of Basic objects : ΔΦ of leading Jets
• Discrepancy in Alpgen reduces also close to madGraph, but now main difference in coming from Pythia8
TrackerJetPFJet
JetJPT
CaloJet
13
Comparison of Basic objects : ΔPt of leading Jets
• Distribution in tracker jets are different from others. Combination of charge and neutral hadrons are different in different models.
TrackerJetPFJet
JetJPT
CaloJet
14
Comparison of Basic objects : Pt2 sin(ΔΦ)/Pt1 of leading Jets
• Deviation in Alpgen and Madgraph are opposite to Pythia8.
• Simplue guess : Alpgen/Madgraph, Thrust value is larger, opposite in Pythia8
TrackerJetPFJet
JetJPT
CaloJet
15
Comparison of event shape variables
• Data with only statistical error
• MC samples
– Pythia6
– Pythia8
– Herwig++
– Alpgen
– Madgraph
• D6T and P0 tuning of Pythia6 are consistent with each other
• Herwig+Jimmy is also consistent with Herwig++
16
Systematic uncertainty and Sensitivity
• Systematic uncertainty:
– Jet Energy and Position Resolution (on MC)
– Jet Energy Scale (on Data)
– Eta dependent Jet Energy Scale (on Data)
• Sensitivity :
– Jet Types
– Jet Algorithms
– Underlying event
– Initial State Radiation
– Final State Radiation
17
Effect of Jet Energy Scale on Event Shape Variables (±5%) : An example
• Most of the sample is common, more (less) events are accepted with increase (decrease) in JES
• 3% uncertainty
• Effect of eta dependent scale uncertainty is negligible
Thrust Minor
18
• Recommendations: - 10 % uncertainty in the sigma of the jet energy resolution curves - compare the distributions with the default sigma, 1.1×σ and 0.9×σ
Jet Energy and position Resolution Uncertainty
The jet energy resolution uncertainty leads to deviations within 2-4% over most of the range
19
Comparison of various Jet types in dataThrust Minor
• Difference in Different types, is it same in MC too ?All are normalised to total numbers of entries in Calo objects
20
Effects of Jet constituents/Algorithm on the comparison of Data and MC
• Double ratio : (Type1/Type2)Data / (Type1/Type2)MC
Consistent with ONE, but need more statisticsOnly one (maximum) error in Data and MC are considered
21
Effects of Jet Pt/eta criteria• Double ratio : (Sel1/Sel2)Data / (Sel1/Sel2)MC
Consistent with ONE, but need more statisticsConsistent with one, but need to look with larger statistics
In PAS
22
Stability over time
23
ResultsYellow Error band contains systematic and statistical uncertainties on data and MC, the black error bar shows the statistical error on Data only
Pythia and Herwig++ are close to the data,Alpgen,Madgraph and Pythia8 show large discrepancies
24
Thrust Minor and Y23
• Pythia8 differs in Thrust/Minor, but not in Y23, splitting of jets into
two looks fine in pythia8. Very sensitive to αS
Minor Y23
25
Comparison with two and three jet events
• With only two jet events, Alpgen/Madgraph and Pythai8 differ from data, which was predicted from simple Pt2 sin(ΔΦ)/Pt1 distribution
2-jet
3-jet
26
Comparison with Pt> 45 and 60 GeV on all jets
• Same as 30 GeV criteia
45GeV
60GeV
27
Central Thrust and Thrust Minor with 60GeV crit (HLT_Jet15U)
• Same as 90GeV/c criteria
MinorThrust
28
Summary
• First measurements of central event shape variables from pp collision data at cm energy of 7 TeV
• Several types of jets are used in the analysis : CaloJet, JetJPT, PFJet, TrackerJet
• Systematic uncertainty in the measurements studied due to
– Jet energy scale (constant as well as η dependent scale)
– Jet energy and position resolution for MC predictions
• Measurements are compared with several QCD inspired models
– Reasonable agreement with different tunes PYTHIA6 and HERWIG(++)
– ALPGEN, MADGRAPH and PYTHIA8, with default CMS parameter tunes, show significant discrepancies with data
– Talked with different Generator people about this discrepancy
29
Central Thrust and Thrust Minor with only two jet events
• Same as all events
MinorThrust
30
Comparison of Basic objects : PT of leading jets
• Looks fine
31
Comparison of Basic objects : Pesudorapidity
• A dip in Data around |eta|=1.3
32
Comparison of Basic objects : Azimuthal angle
• A periodicity is observed, less in tracker jet
33
JetJPT trigger
With matching Trigger jets within Δr < 0.15
34
Systematic/Sensitivity
• But used only JER, JES, JES(η)V01-09-01-09 CondFormats/JetMETObjects V00-02-13 CommonTools/RecoAlgos V03-28-04 DataFormats/JetReco V04-03-05 RecoJets/JetProducers
35
Effect of inter calibration of calo towers (4%)
• Most of the sample is common
• Average shift is ~2%
Thrust Minor
36
Effect of Jet cleaning criteria, loose vs tight
• Calo : JPT : + fHHP < 0.95 and EMfrac<0.9
• PF : + EM(HAD)energy fraction < 0.9
• Rejection : 6.0/3.6/0.9 for CaloJet, JetJPT, PFJet
Thrust Minor
Samples differ by 3% only, effect <1% effect
37
Comparison of various Jet Algorithms
• Observe a variation, which is expected due to different algorithms
Thrust Minor
38
Trigger criteria of Tracker Jet