BDT Analysis

BDT Training Information:

To provide better rejection against the major backgrounds (ZZ and ttZ), a total of 4 different BDTs are trained (2 per signal process, and 2 per channel). Enumerating this, we have:

• WWZ vs Backgrounds (ZZ,ttZ) in the opposite-flavor channel
• ZH vs Backgrounds (ZZ,ttZ) in the opposite-flavor channel
• WWZ vs Backgrounds (ZZ,ttZ) in the same-flavor channel
• ZH vs Backgrounds (ZZ,ttZ) in the same-flavor channel

For the first version of the BDT (v1), the important information is listed below:

• List of input variables that were trained on is here
• xml files containing the weights for the opposite flavor and same flavor BDTs
• Plots will be shown here (WIP)

Training Region (TR) Selection

Events passed to the BDT for training and testing are subject to the so-called "training region" selection, which is a subset of the full cut-based selection. A slide showing the training region selection can be found below:

• Training region selection (v1): here (slide 3)

• Lepton p_T : We require the leading (subleading) lepton in the event to have p_T > 25 (15) GeV . The third and fourth leptons in the event are both required to have p_T > 10 GeV .
• Z Candidate Selection: The pair of leptons passing the above Preselection requirement with same flavor, opposite charge, that have an invariant mass closest to the Z boson mass. Both leptons are also subject to the following requirements:

• W Candidate Selection: The remaining two leptons (the non-Z candidates) passing the above Preselection requirements are then chosen as the W lepton candidates. We require the W lepton candidates to have opposite charge. Both leptons are subject to the following additional requirements:

Combined Significance: using signal+background MC in the 4-lepton SRs, we obtain a combined significance of 4.46σ (via Higgs Combine Tool)

/ceph/cms/store/user/kdownham/VVVAnalysis/050123/

Most recent version

The most up-to-date version of the skims is an inclusive 3-lepton skim that is used for both the 3-lepton+tau and 4-lepton analyses. It can be found in Keegan's storage area on ceph in the following directory:

/ceph/cms/store/user/kdownham/skimOutput/3LepTau_4Lep/

This set of skims is compatible with the new lepton ID (TOP-UL MVA ID) and utilizes the following selection criteria for leptons:

• 3 or more leptons (electrons or muons) satisfying

Cut Based Analysis (4-lepton channel)

Preliminary (Baseline) Results

• Preselection: exactly 4 leptons satisfying the following criteria
  • Muons:
    • p_T > 10 GeV
    • |η| < 2.4
    • |d_xy| < 0.05 cm
    • |d_z| < 0.1 cm
    • |IP_3D/σ_IP3D| < = 8
    • miniPFRelIso_all < 0.4
    • mediumId = true
    • MVA score > 0.64
  • Electrons:
    • p_T > 10 GeV
    • |η| < 2.5
    • |d_xy| < 0.05 cm
    • |d_z| < 0.1 cm
    • |IP_3D/σ_IP3D| < = 8
    • miniPFRelIso_all < 0.4
    • lostHits < = 1
    • convVeto = true
    • tightCharge = 2
    • MVA score > 0.81
• Z Candidate Selection: The pair of leptons passing the above Preselection requirement with same flavor, opposite charge, that have an invariant mass closest to the Z boson mass. Both leptons are also subject to the following p_T and m_ll requirements:
  • leading Z candidate lepton: p_T > 25 GeV
  • subleading Z candidate lepton: p_T > 15 GeV
  • |m_ll - m_Z| < 10 GeV
  • both leptons: |IP_3D/σ_IP3D| < 4
  • for electrons: relIso03_all < 0.2
• W Candidate Selection: The remaining two leptons (the non-Z candidates) passing the above Preselection requirements are then chosen as the W lepton candidates. We require the W lepton candidates to have opposite charge. Both leptons are subject to the following p_T requirements:
  • leading W candidate lepton: p_T > 25 GeV
  • subleading W candidate lepton: p_T > 15 GeV
  • both leptons: |IP_3D/σ_IP3D| < 4
  • for electrons: relIso03_all < 0.2
• QCD low mass resonance veto: Any opposite charge pair of leptons must have an invariant mass > 12 GeV
• b-tagged jet veto: selected events must have no b-tagged jets
  • b-tagged jets: jets passing loose WP of btagDeepB algorithm

• Muons
  • miniPFRelIso_all < 0.4
  • mediumId = true
  • |η| < 2.4
  • p_T > 10 GeV
• Electrons
  • miniPFRelIso_all < 0.4
  • |η| < 2.5
  • p_T > 10 GeV

Skims for testing the new lepton ID can be found in Keegan's ceph area on UAF: /ceph/cms/store/user/kdownham/skimOutput/WWZ_newLepID/

Pre-Selection (Old Lepton ID)

Pre-Selection (New Lepton ID)

Presentations

<-- /editTable -->

Preliminary Results

• ee/μμ:

• eμ:

Signal Regions

Events in the eμ (ee/μμ) category are further separated into four (three) signal regions (SRs) based on m_ll,Wcands (p_T,miss, p_T,4l). The signal regions for both categories are given below:

• eμ:
  • Bin A: p_T,miss > 120 GeV
  • Bin B: 70 GeV < p_T,miss < 120 GeV , 40 GeV < p_T,4l < 70 GeV
  • Bin C: 70 GeV < p_T,miss < 120 GeV , 70 GeV < p_T,4l
• ee/μμ:
  • Bin 1: 0 GeV < m_ll,Wcands < 40 GeV
  • Bin 2: 40 GeV < m_ll,Wcands < 60 GeV
  • Bin 3: 60 GeV < m_ll,Wcands < 100 GeV
  • Bin 4: 100 GeV < m_ll,Wcands

• eμ: The main backgrounds in this category are ZZ--> ττ --> eμ (for m_ll,Wcands < 100 GeV ) and ttZ (for m_ll,Wcands > 100 GeV ). The ZZ background is reduced heavily by cutting on the m_T2 variable, while the ttZ background is largely unaffected by cutting on m_T2 due to the similar kinematics as the signal. Because of this, events with m_ll,Wcands < 100 GeV are required to have m_T2 > 25 GeV , while events with m_ll,Wcands > 100 GeV are not subject to any cut on m_T2.

• • W+Jets Background MC (2018):
    • /WJetsToLNu_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /WJetsToLNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
  • W+Jets Background MC (2017):
    • /WJetsToLNu_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /WJetsToLNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
  • W+Jets Background MC (2016):
    • /WJetsToLNu_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /WJetsToLNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
    • /WJetsToLNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
  • DY+Jets Background MC (2018):
    • /DYJetsToLL_M-50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /DYJetsToLL_M-10to50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • DY+Jets Background MC (2017):
    • /DYJetsToLL_M-50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /DYJetsToLL_M-10to50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
  • DY+Jets Background MC (2016):
    • /DYJetsToLL_M-50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /DYJetsToLL_M-50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /DYJetsToLL_M-10to50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /DYJetsToLL_M-10to50_TuneCP5_13TeV-madgraphMLM-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
  • ttbar Background MC (2018):
    • /TTTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /TTToSemiLeptonic_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • ttbar Background MC (2017):
    • /TTTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /TTToSemiLeptonic_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
  • ttbar Background MC (2016):
    • /TTTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /TTTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /TTToSemiLeptonic_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /TTToSemiLeptonic_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
  • WW Background MC (2018):
    • /WWTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
  • WW Background MC (2017):
    • /WWTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
  • WW Background MC (2016):
    • /WWTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /WWTo2L2Nu_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
  • ttH Background MC (2018):
    • /ttHJetToNonbb_M125_TuneCP5_13TeV_amcatnloFXFX_madspin_pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • ttH Background MC (2017):
    • /ttHJetToNonbb_M125_TuneCP5_13TeV_amcatnloFXFX_madspin_pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
  • ttH Background MC (2016):
    • /ttHJetToNonbb_M125_TuneCP5_13TeV_amcatnloFXFX_madspin_pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /ttHJetToNonbb_M125_TuneCP5_13TeV_amcatnloFXFX_madspin_pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM

• • • /GluGluZH_HToWWTo2L2Nu_M125_13TeV_powheg_pythia8_TuneCP5_PSweights/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM

• • • /GluGluZH_HToWWTo2L2Nu_M125_13TeV_powheg_pythia8_TuneCP5_PSweights/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM

• • • /HZJ_HToWWTo2L2Nu_ZTo2L_M-125_TuneCP5_13TeV-powheg-jhugen727-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM

• • • /GluGluZH_HToWWTo2L2Nu_M-125_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM

• • • /GluGluZH_HToWWTo2L2Nu_M125_13TeV_powheg_pythia8_TuneCP5_PSweights/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM

• • • /VHToNonbb_M125_TuneCP5_13TeV-amcatnloFXFX_madspin_pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM

• • • /ZZTo4Q_5f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM

• • • /ZZTo4Q_5f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

• • • /ZZTo4Q_5f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM

• • • /GluGluToContinToZZTo2e2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v3/NANOAODSIM

• • • /TTZToLL_M-1to10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM

• • • /TTZToLL_M-1to10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

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• • • /WZTo1L1Nu2Q_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /WZTo1L3Nu_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM

• • • /WZTo1L1Nu2Q_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /WZTo1L3Nu_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

• • • /WZTo1L1Nu2Q_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /WZTo1L3Nu_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM

• • • /ZZ_TuneCP5_13TeV-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM

• • • /ZZTo2L2Nu_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /ZZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /ZZTo2Q2Nu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /ZZTo4Q_5f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /GluGluToContinToZZTo2e2mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo2e2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo2e2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo2mu2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo2mu2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo4e_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo4mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluToContinToZZTo4tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM

• • • /ZZ_TuneCP5_13TeV-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM

• • • /ZZTo2L2Nu_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /ZZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /GluGluToContinToZZTo2e2mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo2e2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo2e2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo2mu2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo2mu2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo4e_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo4mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluToContinToZZTo4tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM

• • • /ZZ_TuneCP5_13TeV-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

• • • /ZZTo2L2Nu_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /ZZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo2e2mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo2e2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo2e2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo2mu2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo2mu2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo4e_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo4mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /GluGluToContinToZZTo4tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /ZZ_TuneCP5_13TeV-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /ZZTo2L2Nu_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /ZZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /GluGluToContinToZZTo2e2mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /GluGluToContinToZZTo2e2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /GluGluToContinToZZTo2mu2nu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /GluGluToContinToZZTo2mu2tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /GluGluToContinToZZTo4e_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /GluGluToContinToZZTo4mu_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /GluGluToContinToZZTo4tau_TuneCP5_13TeV-mcfm701-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM

• • • /TTZToLLNuNu_M-10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /TTZToQQ_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
  • tWZ Background MC (2018):
    • /ST_tWll_5f_TuneCP5_13TeV-madgraph-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • tWZ Background MC (2017):
    • /ST_tWll_5f_TuneCP5_13TeV-madgraph-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
  • tWZ Background MC (2016):
    • /ST_tWll_5f_TuneCP5_13TeV-madgraph-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

• • • /WZ_TuneCP5_13TeV-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /WZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v2/NANOAODSIM
    • /WZTo3LNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM

• • ttZ Background MC (2018):
    • /TTZToLL_M-1to10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /TTZToLLNuNu_M-10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /TTZToQQ_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • ttZ Background MC (2017):
    • /TTZToLLNuNu_M-10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /TTZToQQ_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
  • ttZ Background MC (2016):
    • /TTZToLLNuNu_M-10_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /TTZToQQ_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
  • WZ Background MC (2018):
    • /WZ_TuneCP5_13TeV-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /WZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /WZTo3LNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /WZTo1L1Nu2Q_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /WZTo1L3Nu_4f_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • WZ Background MC (2017):
    • /WZ_TuneCP5_13TeV-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /WZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /WZTo3LNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
  • WZ Background MC (2016):
    • /WZ_TuneCP5_13TeV-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /WZTo2Q2L_mllmin4p0_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
    • /WZTo3LNu_TuneCP5_13TeV-amcatnloFXFX-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

• • pfRelIso03_all < 0.4

• • |η| < 2.4

• • • • |IP_3D/σ_IP3D| < 4
      • I_{rel,R=0.3,EA,Lep} < 0.2 (Not used)

• • • • |IP_3D/σ_IP3D| < 4
      • I_{rel,R=0.3,EA,Lep} < 0.2 (Not used)

• • • • |IP_3D/σ_IP3D| < 4

• • • • |IP_3D/σ_IP3D| < 4

• ee/μμ: The main background in this category is ZZ--> 4l. No additional selection is applied to this category prior to binning (see sec. "Binning").

Event Categorization

• eμ: The main backgrounds in this category are ZZ--> ττ --> eμ (for m_ll < 100 GeV ) and ttZ (for m_ll > 100 GeV ). The ZZ background is reduced heavily by cutting on the m_T2 variable, while the ttZ background is largely unaffected by cutting on m_T2 due to the similar kinematics as the signal. Because of this, events with m_ll < 100 GeV are required to have m_T2 > 25 GeV , while events with m_ll > 100 GeV are not subject to any cut on m_T2.
• ee/μμ

• • • /WWZJetsTo4L2Nu_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /HZJ_HToWWTo2L2Nu_ZTo2L_M-125_TuneCP5_13TeV-powheg-jhugen727-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_M-125_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /VHToNonbb_M125_TuneCP5_13TeV-amcatnloFXFX_madspin_pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM

• • • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9_ext1-v2/NANOAODSIM
    • /WWZJetsTo4L2Nu_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /HZJ_HToWWTo2L2Nu_ZTo2L_M-125_TuneCP5_13TeV-powheg-jhugen727-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_M-125_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /VHToNonbb_M125_TuneCP5_13TeV-amcatnloFXFX_madspin_pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM

• • • /WWZJetsTo4L2Nu_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
    • /HZJ_HToWWTo2L2Nu_ZTo2L_M-125_TuneCP5_13TeV-powheg-jhugen727-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_M-125_TuneCP5_13TeV-powheg-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_M125_13TeV_powheg_pythia8_TuneCP5_PSweights/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
    • /VHToNonbb_M125_TuneCP5_13TeV-amcatnloFXFX_madspin_pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v2/NANOAODSIM
  • ZZ Background MC (2018):
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v2/NANOAODSIM
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL18NanoAODv9-20UL18JMENano_106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
  • ZZ Background MC (2017):
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v2/NANOAODSIM
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL17NanoAODv9-20UL17JMENano_106X_mc2017_realistic_v9-v1/NANOAODSIM
  • ZZ Background MC (2016):
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /ZZTo4L_TuneCP5_13TeV_powheg_pythia8/RunIISummer20UL16NanoAODv9-20UL16JMENano_106X_mcRun2_asymptotic_v17-v1/NANOAODSIM

• • looseId = 1

• • p_T > 10 GeV
  • pfIsoId >= 1

• • mvaFall17V2noIso_WPL = 1

• • p_T > 10 GeV
  • pfRelIso03_all > 0.4

Pre-Selection

• Preselection: exactly 4 leptons satisfying the Common veto ID (see section "Skimming" for the definition)
• Lepton IDs: Leptons are categorized as a Z-candidate or a W-candidate. The criteria for electron and muon IDs for W and Z candidates are
  • Electrons
    • Z candidate (ZID)
      • ID: MVA POG Loose NoIso
      • |IP_3D/σ_IP3D| < 4
      • I_{rel,R=0.3,EA,Lep} < 0.2
    • W candidate (WID)
      • ID: MVA 90% Iso
      • |IP_3D/σ_IP3D| < 4
      • I_{rel,R=0.3,EA,Lep} < 0.2
  • Muons
    • Z candidate (ZID)
      • ID: Medium
      • |IP_3D/σ_IP3D| < 4
      • I_{rel,R=0.4,Δβ} < 0.25
    • W candidate (WID)
      • ID: Medium
      • |IP_3D/σ_IP3D| < 4
      • I_{rel,R=0.4,Δβ} < 0.15
• Z Candidate Selection: The pair of leptons passing the ZID requirement with same flavor, opposite charge, that have an invariant mass closest to the Z boson mass. Both leptons are also subject to the following p_T and m_ll requirements:
  • leading Z candidate lepton: p_T > 25 GeV
  • subleading Z candidate lepton: p_T > 15 GeV
  • |m_ll - m_Z| < 10 GeV
• W Candidate Selection: The remaining two leptons (the non-Z candidates) passing the WID requirements are then chosen as the W lepton candidates. We require the W lepton candidates to have opposite charge. Both leptons are subject to the following p_T requirements:
  • leading W candidate lepton: p_T > 25 GeV
  • subleading W candidate lepton: p_T > 15 GeV
• QCD low mass resonance veto: Any opposite charge pair of leptons must have an invariant mass > 12 GeV
• b-tagged jet veto: selected events must have no b-tagged jets

WWZ Run 3 Analysis

Meetings (weekly)

*Thursday, 1:00 pm (CA) / 4:00 pm (FL)

Meetings are held in Philip's Zoom room

People

Claudio Campagnari (UCSB)
Philip Chang (UF)
Keegan Downham (UCSB)
Matthew Dittrich (UF)

Data and MC Samples

• MC Samples
  • Signal MC (2018):
    
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1-v1/NANOAODSIM
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL18NanoAODv9-106X_upgrade2018_realistic_v16_L1v1_ext1-v2/NANOAODSIM
    • /WWZJetsTo4L2Nu_4f_TuneCP5_13TeV_amcatnloFXFX_pythia8/RunIIAutumn18NanoAODv6-Nano25Oct2019_102X_upgrade2018_realistic_v20-v1/NANOAODSIM
    • /WWZ_TuneCP5_13TeV-amcatnlo-pythia8/RunIIAutumn18NanoAODv6-Nano25Oct2019_102X_upgrade2018_realistic_v20_ext1-v1/NANOAODSIM
    • /HZJ_HToWWTo2L2Nu_ZTo2L_M125_13TeV_powheg_jhugen714_pythia8_TuneCP5/RunIIAutumn18NanoAODv6-Nano25Oct2019_102X_upgrade2018_realistic_v20-v1/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_ZTo2L_M125_13TeV_powheg_pythia8_TuneCP5_PSweights/RunIIAutumn18NanoAODv6-Nano25Oct2019_102X_upgrade2018_realistic_v20-v1/NANOAODSIM
  • Signal MC (2017):
    
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL17NanoAODv9-106X_mc2017_realistic_v9-v1/NANOAODSIM
    • /WWZJetsTo4L2Nu_4f_TuneCP5_13TeV_amcatnloFXFX_pythia8/RunIIFall17NanoAODv6-PU2017_12Apr2018_Nano25Oct2019_102X_mc2017_realistic_v7-v1/NANOAODSIM
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIIFall17NanoAODv6-PU2017_12Apr2018_Nano25Oct2019_ext_102X_mc2017_realistic_v7-v1/NANOAODSIM
    • /HZJ_HToWWTo2L2Nu_ZTo2L_M125_13TeV_powheg_jhugen714_pythia8_TuneCP5/RunIIFall17NanoAODv6-PU2017_12Apr2018_Nano25Oct2019_102X_mc2017_realistic_v7-v1/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_ZTo2L_M125_13TeV_powheg_pythia8_TuneCP5/RunIIFall17NanoAODv6-PU2017_12Apr2018_Nano25Oct2019_102X_mc2017_realistic_v7-v1/NANOAODSIM
  • Signal MC (2016):
    
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17-v1/NANOAODSIM
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODv9-106X_mcRun2_asymptotic_v17_ext1-v1/NANOAODSIM
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11-v1/NANOAODSIM
    • /WWZ_4F_TuneCP5_13TeV-amcatnlo-pythia8/RunIISummer20UL16NanoAODAPVv9-106X_mcRun2_asymptotic_preVFP_v11_ext1-v1/NANOAODSIM
    • /WWZ_TuneCUETP8M1_13TeV-amcatnlo-pythia8/RunIISummer16NanoAODv6-PUMoriond17_Nano25Oct2019_102X_mcRun2_asymptotic_v7-v1/NANOAODSIM
    • /HZJ_HToWWTo2L2Nu_ZTo2L_M125_13TeV_powheg_pythia8/RunIISummer16NanoAODv6-PUMoriond17_Nano25Oct2019_102X_mcRun2_asymptotic_v7-v1/NANOAODSIM
    • /GluGluZH_HToWWTo2L2Nu_ZTo2L_M125_13TeV_powheg_pythia8/RunIISummer16NanoAODv6-PUMoriond17_Nano25Oct2019_102X_mcRun2_asymptotic_v7-v1/NANOAODSIM

The full list of samples can be found here.

Skimming

There will be 2 sets of skims for 2016-2018 data/MC: an inclusive 4-lepton skim and a 3-lepton skim. I propose that the leptons satisfy the Common veto ID (defined in AN2019_144_v9, table 7) and summarized as follows:

• Muons
  • ID: Loose
  • |η| < 2.4
  • |d_z| < 0.1 cm
  • |d_xy| < 0.05 cm
  • I_{rel,R=0.3,EA,Lep} < 0.4
• Electrons
  • ID: MVA POG Loose NoIso
  • |η| < 2.5
  • |d_z| < 0.1 cm
  • |d_xy| < 0.05 cm
  • I_{rel,R=0.3,EA,Lep} < 0.4

I also propose that all leptons satisfy some moderate p_T requirement, say p_T > 10 GeV .