Perspectives on Physics and on CMS at Very High Luminosity ?
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Perspectives on Physics and on CMS at Very High Luminosity Are the QCD MC Models Ready for High Luminosity? Rick Field University of Florida Alushta, Crimea, Ukraine, May 2012 Outline Outgoing Parton How Universal are the QCD MC Model Tunes? • Do we need a separate tune for each center-of-mass energy? 900 GeV, 1.96 TeV, 7 TeV, etc. • Do we need a separate tune for each hard QCD subprocess? Jet Production, Drell-Yan Production, etc. • Do we need separate tunes for “Min-Bias” (MB) and the “underlying event” (UE) in a hard scattering process? A close look at two PYTHIA tunes: • PYTHIA 6.2 Tune DW (CDF UE tune). • PYTHIA 6.4 Tune Z1 (CMS UE tune). PT(hard) Initial-State Radiation Proton Proton Underlying Event Underlying Event Outgoing Parton Final-State Radiation High PT Z-Boson Production Outgoing Parton Initial-State Radiation Proton AntiProton Z-boson Pile-Up: A quick look at the fluctuations in pile-up. New CDF UE Data: The Tevatron Energy Scan (300 GeV, “Minimum Bias” Collisions Proton Proton 900 GeV, 1.96 TeV). CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 1 QCD Monte-Carlo Models: High Transverse Momentum Jets Hard Scattering Initial-State Radiation Hard Scattering “Jet” Initial-State Radiation “Jet” Outgoing Parton PT(hard) Outgoing Parton PT(hard) Proton “Hard Scattering” Component AntiProton Final-State Radiation Outgoing Parton Underlying Event Underlying Event Proton “Jet” Final-State Radiation AntiProton Underlying Event Outgoing Parton Underlying Event “Underlying Event” Start with the perturbative 2-to-2 (or sometimes 2-to-3) parton-parton scattering and add initial and finalstate gluon radiation (in the leading log approximation or modified leading log approximation). The “underlying event” consists of the “beam-beam remnants” and from particles arising from soft or semi-soft multiple parton interactions (MPI). The “underlying event” is“jet” an unavoidable Of course the outgoing colored partons fragment into hadron and inevitably “underlying event” background to most collider observables observables receive contributions from initial and final-state radiation. and having good understand of it leads to more precise collider measurements! CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 2 QCD Monte-Carlo Models: Lepton-Pair Production Lepton-Pair Production High PT Z-Boson Production Anti-Lepton Outgoing Parton Initial-State Initial-State Radiation Radiation High P T Z-Boson Production Lepton-Pair Production Initial-State Initial-StateRadiation Radiation “Jet” Proton Proton Final-State Radiation Outgoing Parton Anti-Lepton Final-State Radiation “Hard Scattering” Component AntiProton AntiProton Underlying Event Lepton Z-boson Underlying Event Proton Lepton Z-boson Underlying Event AntiProton Underlying Event “Underlying Event” Start with the perturbative Drell-Yan muon pair production and add initial-state gluon radiation (in the leading log approximation or modified leading log approximation). The “underlying event” consists of the “beam-beam remnants” and from particles arising from soft or semi-soft multiple parton interactions (MPI). Of course the outgoing colored partons fragment into hadron “jet” and inevitably “underlying event” observables receive contributions from initial-state radiation. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 3 Traditional Approach CDF Run 1 Analysis Charged Particle ∆φ Correlations Leading Calorimeter Jet or Charged Jet #1 Leading Charged Particle Jet or PT > PTmin |η η| < ηcut Direction Leading Charged Particle or 2π π Away RegionZ-Boson “Transverse” region very sensitive to the “underlying event”! “Toward-Side” Jet ∆φ “Toward” “Transverse” “Transverse” Leading Object Direction ∆φ “Toward” “Transverse” Transverse Region φ Leading Object Toward Region “Transverse” Transverse Region “Away” “Away” Away Region 0 “Away-Side” Jet -η ηcut η +η ηcut Look at charged particle correlations in the azimuthal angle ∆φ relative to a leading object (i.e. CaloJet#1, ChgJet#1, PTmax, Z-boson). For CDF PTmin = 0.5 GeV/c ηcut = 1. o o o o Define |∆φ ∆φ| ∆φ| ∆φ| ∆φ < 60 as “Toward”, 60 < |∆φ ∆φ < 120 as “Transverse”, and |∆φ ∆φ > 120 as “Away”. o All three regions have the same area in η-φφ space, ∆η×∆φ ηcut×120 = 2η ηcut×2π π/3. Construct ∆η ∆φ = 2η densities by dividing by the area in η-φ φ space. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 4 “Transverse” Charged Density PTmax Direction ηdφ φ "Transverse" Charged Particle Density: dN/dη ∆φ 1.6 “Transverse” “Transverse” “Away” ChgJet#1 Direction ∆φ “Toward” “Transverse” “Transverse” “Away” "Transverse" Charged Density “Toward” RDF Preliminary 7 TeV py Tune DW generator level 1.2 PTmax 0.8 ChgJet#1 DY(muon-pair) 70 < M(pair) < 110 GeV 0.4 Charged Particles (|η η|<1.0, PT>0.5 GeV/c) 0.0 Muon-Pair Direction ∆φ 0 5 10 15 20 25 30 35 40 45 50 PT(chgjet#1) or PTmax or PT(pair) (GeV/c) “Toward” “Transverse” “Transverse” “Away” Shows the charged particle density in the “transverse” region for charged particles (pT > 0.5 GeV/c, |η η| < 1) at 7 TeV as defined by PTmax, PT(chgjet#1), and PT(muon-pair) from PYTHIA Tune DW at the particle level (i.e. generator level). Charged particle jets are constructed using the Anti-KT algorithm with d = 0.5. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 5 Min-Bias “Associated” Charged Particle Density ηdφ φ "Transverse" Charged Particle Density: dN/dη "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.2 RDF Preliminary 14 TeV Min-Bias "Transverse" Charged Density "Transverse" Charged Density 1.2 py Tune DW generator level 10 TeV 7 TeV 0.8 1.96 TeV 0.9 TeV 0.4 0.2 TeV Charged Particles (|η η|<1.0, PT>0.5 GeV/c) RDF Preliminary LHC14 py Tune DW generator level 0.8 LHC10 LHC7 Tevatron 900 GeV 0.4 PTmax = 5.25 GeV/c RHIC Charged Particles (|η η|<1.0, PT>0.5 GeV/c) 0.0 0.0 0 5 10 15 20 0 25 2 PTmax Direction “Toward” RHIC “Transverse” “Transverse” 6 8 10 14 PTmax Direction PTmax Direction 0.2 TeV → 1.96 TeV (UE increase ~2.7 times) Tevatron “Away” 12 Center-of-Mass Energy (TeV) PTmax (GeV/c) ∆φ 4 ∆φ “Toward” “Transverse” 1.96 TeV → 14 TeV (UE increase ~1.9 times) LHC ∆φ “Toward” “Transverse” “Transverse” “Transverse” “Away” “Away” Shows the “associated” charged particle density in the “transverse” region as a function of PTmax for charged particles (pT > 0.5 GeV/c, |η η| < 1, not including PTmax) for “min-bias” events at 0.2 TeV, 0.9 TeV, 1.96 TeV, 7 TeV, 10 TeV, 14 TeV predicted by PYTHIA Tune DW at the particle level (i.e. generator level). CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 6 Min-Bias “Associated” Charged Particle Density ηdφ φ "Transverse" Charged Particle Density: dN/dη "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.2 RDF Preliminary 14 TeV Min-Bias "Transverse" Charged Density "Transverse" Charged Density 1.2 py Tune DW generator level 10 TeV 7 TeV 0.8 1.96 TeV 0.9 TeV 0.4 0.2 TeV Charged Particles (|η η|<1.0, PT>0.5 GeV/c) RDF Preliminary LHC14 py Tune DW generator level 0.8 LHC10 LHC7 Tevatron 900 GeV 0.4 PTmax = 5.25 GeV/c RHIC Charged Particles (|η η|<1.0, PT>0.5 GeV/c) 0.0 0.0 0 5 10 15 20 0 25 2 PTmax Direction “Toward” RHIC “Transverse” “Transverse” 6 8 10 14 PTmax Direction PTmax Direction 0.2 TeV → 1.96 TeV (UE increase ~2.7 times) Tevatron “Away” 12 Center-of-Mass Energy (TeV) PTmax (GeV/c) ∆φ 4 ∆φ “Toward” “Transverse” 1.96 TeV → 14 TeV (UE increase ~1.9 times) LHC ∆φ “Toward” “Transverse” “Transverse” “Transverse” “Away” “Away” Shows the “associated” charged particle density in the “transverse” region as a function of PTmax for charged particles (pT > 0.5 GeV/c, |η η| < 1, not including PTmax) for “min-bias” events at 0.2 TeV, 0.9 TeV, 1.96 TeV, 7 TeV, 10 TeV, 14 TeV predicted by PYTHIA Tune DW at the Linear scale! particle level (i.e. generator level). CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 7 PYTHIA Tune DW "Transverse" Charged Particle Density: dN/dη ηdφ φ ηdφ φ "Transverse" Charged Particle Density: dN/dη Charged Particle Density CMS Preliminary "Transverse" Charged Density 1.2 7 TeV data uncorrected pyDW + SIM 0.8 CMS 900 GeV 0.4 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 1.2 RDF Preliminary 7 TeV ATLAS corrected data Tune DW generator level 0.8 ATLAS 900 GeV 0.4 Charged Particles (|η η|<2.5, PT>0.5 GeV/c) 0.0 0.0 0 5 10 15 20 25 30 35 40 45 50 0 2 4 6 8 10 CMS preliminary data at 900 GeV and 7 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle jet (chgjet#1) for charged particles with pT > 0.5 GeV/c and |η η| < 2. The data are uncorrected and compared with PYTHIA Tune DW after detector simulation. 16 18 20 ATLAS preliminary data at 900 GeV and 7 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 2.5. The data are corrected and compared with PYTHIA Tune DW at the generator level. PT(chgjet#1) Direction PTmax Direction ∆φ ∆φ “Toward” “Toward” “Transverse” “Transverse” “Away” CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 14 PTmax (GeV/c) PT(chgjet#1) GeV/c “Transverse” 12 “Transverse” “Away” Rick Field – Florida/CDF/CMS Page 8 PYTHIA Tune DW "Transverse" Charged Particle Density: dN/dη ηdφ φ ηdφ φ "Transverse" Charged Particle Density: dN/dη Charged Particle Density CMS Preliminary "Transverse" Charged Density 1.2 7 TeV data uncorrected pyDW + SIM 0.8 CMS 900 GeV 0.4 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 1.2 RDF Preliminary 7 TeV ATLAS corrected data Tune DW generator level 0.8 ATLAS 900 GeV 0.4 Charged Particles (|η η|<2.5, PT>0.5 GeV/c) 0.0 0.0 0 5 10 15 20 25 30 35 40 45 0 50 2 4 6 8 10 12 14 16 18 20 PTmax (GeV/c) PT(chgjet#1) GeV/c Charged Particle Density CMS preliminary data at 900 GeV and 7 TeV ATLAS preliminary data at 900 GeV and 7 "Transverse" Charged Particle Density: dN/dη ηdφ φ TeV on the “transverse” charged particle on the “transverse” charged particle density, 1.2 Preliminary density, dN/dη ηdφ φ, as defined by the leading dN/dη ηdφ φ, as defined by theRDF leading charged CDF 1.96 TeV data corrected pyDW generatorparticles level Leading particle Jet charged (PTmax) for charged particles particle jet (chgjet#1) for charged with pT > 0.5 GeV/c and |η η| < 2.5. The data are with pT > 0.5 GeV/c and0.8|η η| < 2. The data are corrected and compared with PYTHIA Tune uncorrected and compared with PYTHIA DW at the generator level. Tune DW after detector simulation. PT(chgjet#1) Direction 0.4 PTmax Direction ∆φ “Toward” “Transverse” ∆φ η| < 1.0) Charged Particles (PT>0.5 GeV/c, |η 0.0 “Transverse” “Transverse” 0 “Away” CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 “Toward” 50 100 150 200 250 300 PT(jet#1) GeV/c Rick Field – Florida/CDF/CMS 350 “Transverse” 400 “Away” Page 9 PYTHIA Tune DW "Transverse" Charged Particle Density: dN/dη ηdφ φ "Transverse" Charged Particle Density: dN/dη ηdφ φ 3.0 1.2 CMS Preliminary 7 TeV data uncorrected pyDW + SIM Ratio: 7 TeV/900 GeV Charged Particle Density CMS Preliminary 0.8 Ratio CMS 900 GeV 0.4 data uncorrected pyDW + SIM 2.0 CMS 1.0 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 7 TeV / 900 GeV Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 0.0 0.0 0 5 10 15 20 25 30 35 40 45 50 0 2 4 6 8 10 12 14 16 18 PT(chgjet#1) (GeV/c) PT(chgjet#1) GeV/c CMS preliminary data at 900 GeV and 7 TeV Ratio of CMS preliminary data at 900 GeV and 7 TeV on the “transverse” charged particle on the “transverse” charged particle density, density, dN/dη ηdφ φ, as defined by the leading dN/dη ηdφ φ, as defined by the leading charged charged particle jet (chgjet#1) for charged particle jet (chgjet#1) for charged particles particles with pT > 0.5 GeV/c and |η η| < 2. The with pT > 0.5 GeV/c and |η η| < 2. The data are data are uncorrected and compared with uncorrected and compared with PYTHIA PYTHIA Tune DW after detector simulation. Tune DW after detector simulation. PT(chgjet#1) Direction PT(chgjet#1) Direction ∆φ ∆φ “Toward” “Transverse” “Toward” “Transverse” “Transverse” “Away” CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 “Transverse” “Away” Rick Field – Florida/CDF/CMS Page 10 Charged Particle Density Charged Particle Density: dN/dη ηdφ φ Charged Particle Density: dN/dη ηdφ φ 3 3 CMS Preliminary 1.96 TeV data corrected pyDW generator level Average Charged Density Average Charged Density CDF Run 2 "Away" Drell-Yan Production 70 < M(pair) < 110 GeV 2 1 "Transverse" Charged Particles (|η η|<1.0, PT>0.5 GeV/c) excluding the lepton-pair "Toward" 0 0 10 20 30 40 50 60 70 80 90 7 TeV data corrected pyDW generator level "Away" Drell-Yan Production 60 < M(pair) < 120 GeV 2 "Transverse" 1 "Toward" Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair 0 100 0 20 40 PT(lepton-pair) GeV/c Z-Boson Direction ∆φ High PT Z-Boson Production 60 80 100 PT(lepton-pair) GeV/c Z-Boson Direction Outgoing Parton ∆φ Initial-State Radiation High PT Z-Boson Production Outgoing Parton Initial-State Radiation “Toward” “Toward” Proton “Transverse” CMS Proton AntiProton “Transverse” “Transverse” “Away” Proton “Transverse” “Away” Z-boson Z-boson CDF data at 1.96 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 1 for Drell-Yan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune DW. CMS data at 7 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 2 for DrellYan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune DW. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 11 Charged Particle Density Charged Particle Density: dN/dη ηdφ φ Charged Particle Density: dN/dη ηdφ φ 3 3 CMS Preliminary 1.96 TeV data corrected pyDW generator level Average Charged Density Average Charged Density CDF Run 2 "Away" Drell-Yan Production 70 < M(pair) < 110 GeV 2 1 "Transverse" Charged Particles (|η η|<1.0, PT>0.5 GeV/c) excluding the lepton-pair "Toward" 0 0 10 20 30 40 50 60 70 80 90 Outgoing Parton Initial-State Radiation “Transverse” “Transverse” “Away” "Away" "Transverse" 1 "Toward" Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair 0 100 0 20 40 60 80 100 PT(lepton-pair) GeV/c High P Z-Boson Production CDF: Proton-Antiproton Collisions at 1.96 GeV ∆φ Lepton Cuts: pT > 20 GeV |η η| < 1.0 “Toward” Proton Mass Cut: 70 < M(lepton-pair) < 110 GeV AntiProton Charged Particles: pT > 0.5 GeV/c |η η| < 1.0 T CMS Drell-Yan Production 60 < M(pair) < 120 GeV 2 PT(lepton-pair) GeV/c Z-Boson Direction 7 TeV data corrected pyDW generator level CMS: Proton-Proton High P Z-Boson Production Collisions at 7 GeV ∆φ Lepton Cuts: pT > 20 GeV |η η| < 2.4 “Toward” Mass Cut:Proton 60 < M(lepton-pair) < 120 Proton GeV η| < 2.0 Charged Particles: pT > 0.5 GeV/c |η Z-Boson Direction Outgoing Parton T Initial-State Radiation “Transverse” “Transverse” “Away” Z-boson Z-boson CDF data at 1.96 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 1 for Drell-Yan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune DW. CMS data at 7 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 2 for DrellYan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune DW. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 12 Charged Particle Density 1.96 TeV data corrected pyDW generator level Charged Particle Density Average Charged Density 3 Drell-Yan Production 70 < M(pair) < 110 GeV 2 1 Average Charged Density Large increase in the UE in going from 1.96 TeV Charged Particle Density: dN/dη ηdφ φ Charged Particle Density: dN/dη ηdφ φ "Toward" Charged Particle Density: dN/dη ηdφ φ to 7 TeV as predicted by 3 Tune DW! 1.2 RDF Preliminary CDF RunPYTHIA 2 CMS Preliminary data corrected "Away" pyDW generator level 0.8 Drell-Yan Production Charged Particles (|η GeV/c) η|<1.0, PT>0.5 excluding the lepton-pair 0 10 20 30 40 50 60 0 70 PT(lepton-pair) GeV/c 80 20 90 Initial-State Radiation “Transverse” “Transverse” “Away” "Toward" Charged Particles (PT>0.5 GeV/c) 0 60 PT(lepton-pair) GeV/c Outgoing Parton T "Transverse" 1 100 40 High P Z-Boson Production CDF: Proton-Antiproton Collisions at 1.96 GeV ∆φ Lepton Cuts: pT > 20 GeV |η η| < 1.0 “Toward” Proton Mass Cut: 70 < M(lepton-pair) < 110 GeV AntiProton Charged Particles: pT > 0.5 GeV/c |η η| < 1.0 Z-Boson Direction "Away" Drell-Yan Production 60 < M(pair) < 120 GeV 2 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair 0 0.0 0 CMS CDF 1.96 TeV 0.4 "Transverse" "Toward" 7 TeV data corrected CMS pyDW 7 TeV generator level 2080 40 100 60 80 100 PT(lepton-pair) GeV/c CMS: Proton-Proton High P Z-Boson Production Collisions at 7 GeV ∆φ Lepton Cuts: pT > 20 GeV |η η| < 2.4 “Toward” Mass Cut:Proton 60 < M(lepton-pair) < 120 Proton GeV η| < 2.0 Charged Particles: pT > 0.5 GeV/c |η Z-Boson Direction Outgoing Parton T Initial-State Radiation “Transverse” “Transverse” “Away” Z-boson Z-boson CDF data at 1.96 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 1 for Drell-Yan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune DW. CMS data at 7 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 2 for DrellYan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune DW. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 13 PYTHIA Tune DW Charged Particle Density: dN/dη ηdφ φ "Toward" Charged Particle Density: dN/dη ηdφ φ 3 1.2 CMS 7 TeV data corrected pyDW generator level "Away" Drell-Yan Production 60 < M(pair) < 120 GeV 2 Charged Particle Density Average Charged Density CMS Preliminary "Transverse" 1 "Toward" Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair 0 RDF Preliminary data corrected pyDW generator level CMS 7 TeV 0.8 CDF 1.96 TeV 0.4 Drell-Yan Production 0.0 0 20 40 60 80 100 0 20 40 PT(lepton-pair) GeV/c 80 100 "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.5 1.5 RDF Preliminary Charged Particle Density RDF Preliminary data corrected pyDW generator level CMS 7 TeV 1.0 CDF 1.96 TeV 0.5 60 PT(lepton-pair) GeV/c "Transverse" Charged Particle Density: dN/dη ηdφ φ Charged Particle Density Charged Particles (PT>0.5 GeV/c) CMS 900 GeV CMS 7 TeV data corrected pyDW generator level 1.0 CDF 1.96 TeV 0.5 CMS 900 GeV Charged Particles (PT>0.5 GeV/c) Charged Particles (PT>0.5 GeV/c) 0.0 0.0 0 20 40 60 80 100 0 PT(chgjet#1 or jet#1) GeV/c CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 50 100 150 200 250 PT(chgjet#1 or jet#1) GeV/c Rick Field – Florida/CDF/CMS Page 14 300 PYTHIA Tune DW Charged Particle Density: dN/dη ηdφ φ "Toward" Charged Particle Density: dN/dη ηdφ φ 3 1.2 CMS 7 TeV data corrected pyDW generator level "Away" Drell-Yan Production 60 < M(pair) < 120 GeV 2 Charged Particle Density Average Charged Density CMS Preliminary "Transverse" data corrected pyDW generator level CMS 7 TeV 0.8 CDF 1.96 TeV Overall PYTHIA0.4Tune DW "Toward" is in amazingly good agreement with the Charged Particles (PT>0.5 GeV/c) Drell-Yan Production Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair Tevatron Jet production 0.0 and Drell-Yan data 20 40 60 did a very 80 100 job in 0 predicting 20 60 80 and good the40 PT(lepton-pair) GeV/c PT(lepton-pair) GeV/c LHC Jet production and Drell-Yan data! "Transverse" Charged Particle Density: dN/dη ηdφ φ "Transverse" Charged Particle Density: dN/dη ηdφ φ (although not perfect) 1 0 0 1.5 Charged Particle Density RDF Preliminary data corrected pyDW generator level CMS 7 TeV 1.0 CDF 1.96 TeV 0.5 100 1.5 RDF Preliminary Charged Particle Density RDF Preliminary CMS 900 GeV CMS 7 TeV data corrected pyDW generator level 1.0 CDF 1.96 TeV 0.5 CMS 900 GeV Charged Particles (PT>0.5 GeV/c) Charged Particles (PT>0.5 GeV/c) 0.0 0.0 0 20 40 60 80 100 0 PT(chgjet#1 or jet#1) GeV/c CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 50 100 150 200 250 PT(chgjet#1 or jet#1) GeV/c Rick Field – Florida/CDF/CMS Page 15 300 CMS UE Data ηdφ φ "Transverse" Charged PTsum Density: dPT/dη "Transverse" Charged Particle Density: dN/dη ηdφ φ 2.0 CMS Preliminary CMS Preliminary data corrected Tune Z1 generator level 7 TeV PTsum Density (GeV/c) Charged Particle Density 1.6 1.2 0.8 900 GeV CMS 0.4 Tune Z1 data corrected Tune Z1 generator level 1.6 7 TeV 1.2 CMS 0.8 900 GeV Tune Z1 0.4 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 0.0 0.0 0 10 20 30 40 50 60 70 80 90 100 0 10 PT(chgjet#1) GeV/c CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 30 40 50 60 70 80 90 100 PT(chgjet#1) GeV/c CMS preliminary data at 900 GeV and 7 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle jet (chgjet#1) for charged particles with pT > 0.5 GeV/c and |η η| < 2.0. The data are corrected and compared with PYTHIA Tune Z1 at the generator level. CMS corrected data! 20 CMS preliminary data at 900 GeV and 7 TeV on the “transverse” charged PTsum density, dPT/dη ηdφ φ, as defined by the leading charged particle jet (chgjet#1) for charged particles with pT > 0.5 GeV/c and |η η| < 2.0. The data are corrected and compared with PYTHIA Tune Z1 at the generator level. Very nice agreement! Rick Field – Florida/CDF/CMS CMS corrected data! Page 16 ATLAS UE Data "Transverse" Charged PTsum Density: dPT/dη ηdφ φ "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.5 RDF Preliminary RDF Preliminary 7 TeV ATLAS corrected data Tune Z1 generator level PTsum Density (GeV/c) "Transverse" Charged Density 1.2 0.8 ATLAS 900 GeV 0.4 Tune Z1 7 TeV ATLAS corrected data Tune Z1 generator level 1.0 ATLAS 900 GeV 0.5 Tune Z1 Charged Particles (|η η|<2.5, PT>0.5 GeV/c) Charged Particles (|η η|<2.5, PT>0.5 GeV/c) 0.0 0.0 0 5 10 15 20 25 0 5 10 15 20 25 PTmax (GeV/c) PTmax (GeV/c) ATLAS published data at 900 GeV and 7 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 2.5. The data are corrected and compared with PYTHIA Tune Z1 at the generator level. ATLAS published data at 900 GeV and 7 TeV on the “transverse” charged PTsum density, dPT/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 2.5. The data are corrected and compared with PYTHIA Tune Z1 at the generrator level. ATLAS publication – arXiv:1012.0791 December 3, 2010 CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 17 PYTHIA Tune Z1 Charged Particle Density: dN/dη ηdφ φ Charged Particle Density: dN/dη ηdφ φ 3 3 CMS Preliminary 1.96 TeV data corrected pyZ1 generator level Average Charged Density Average Charged Density CDF Run 2 "Away" Drell-Yan Production 70 < M(pair) < 110 GeV 2 1 "Transverse" Charged Particles (|η η|<1.0, PT>0.5 GeV/c) excluding the lepton-pair "Toward" 0 0 10 20 30 40 50 60 70 80 90 ∆φ High PT Z-Boson Production "Transverse" 1 "Toward" Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair 0 100 0 20 40 60 80 100 PT(lepton-pair) GeV/c Z-Boson Direction Outgoing Parton ∆φ Initial-State Radiation High PT Z-Boson Production Outgoing Parton Initial-State Radiation “Toward” “Toward” Proton “Transverse” "Away" Drell-Yan Production 60 < M(pair) < 120 GeV 2 PT(lepton-pair) GeV/c Z-Boson Direction CMS 7 TeV data corrected pyZ1 generator level Proton AntiProton “Transverse” “Transverse” “Away” Proton “Transverse” “Away” Z-boson Z-boson CDF data at 1.96 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 1 for Drell-Yan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune Z1. CMS data at 7 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 2 for DrellYan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune Z1. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 18 PYTHIA Tune Z1 Tune Z1 describes the energy dependence Charged Particle Density: dN/dη ηdφ φ Charged Particle Density: dN/dη ηdφ φ "Toward" Charged Particle Density: dN/dη ηdφ φ fairly well! 3 1.2 Drell-Yan Production 70 < M(pair) < 110 GeV 2 1 CMS Preliminary RDF Preliminary 1.96 TeV data corrected pyZ1 generator level Charged Particle Density Average Charged Density CDF Run 2 Average Charged Density 3 data corrected "Away" pyZ1 generator level 0.8 Charged Particles (|η PT>0.5 GeV/c) η|<1.0, Production Drell-Yan excluding the lepton-pair 0 10 20 30 40 50 60 0 70 80 20 PT(lepton-pair) GeV/c Z-Boson Direction ∆φ High PT Z-Boson Production 90 "Transverse" 1 "Toward" 0 100 40 0 60 40 100 60 80 100 PT(lepton-pair) GeV/c Z-Boson Direction ∆φ Initial-State Radiation High PT Z-Boson Production Outgoing Parton Initial-State Radiation “Toward” “Toward” Proton “Transverse” 2080 PT(lepton-pair) GeV/c Outgoing Parton Charged Particles (|η η|<2.0, PT>0.5 GeV/c) excluding the lepton-pair Charged Particles (PT>0.5 GeV/c) 0.0 0 "Away" Drell-Yan Production 60 < M(pair) < 120 GeV 2 CDF 1.96 TeV 0.4 "Transverse" "Toward" CMS 7 TeV data corrected pyZ1 generator level CMS 7 TeV Proton AntiProton “Transverse” “Transverse” “Away” Proton “Transverse” “Away” Z-boson Z-boson CDF data at 1.96 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 1 for Drell-Yan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune Z1. CMS data at 7 TeV on the density of charged particles, dN/dη ηdφ φ, with pT > 0.5 GeV/c and |η η| < 2 for DrellYan production as a function of PT(Z) for the “toward”, “away”, and “transverse” regions compared with PYTHIA Tune Z1. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 19 PYTHIA Tune Z1 "Transverse"Charged ChargedParticle ParticleDensity: Density:dN/dη dN/dη dφ "Transverse" ηηdφ φφ 1.2 "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.5 CMSPreliminary Preliminary RDF RDF Preliminary data corrected data corrected Tune generator Z1 generator level pyZ1 level CMS 7 TeV7 TeV 1.0 CDF 1.96 TeV 0.8 900 GeV 0.5 0.4 CMS 900 GeV Tune Z1 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) Charged Particles (PT>0.5 GeV/c) 0.0 0.0 Charged Particle Density Charged Charged Particle Particle Density Density 1.6 1.5 data corrected pyZ1 generator level CMS 7 TeV 1.0 CDF 1.96 TeV 0.5 CMS 900 GeV Tune Z1 Charged Particles (PT>0.5 GeV/c) 0.0 00 10 20 20 30 40 40 50 60 60 70 80 80 90 100 100 0 50 PT(chgjet#1) GeV/c PT(chgjet#1 or jet#1) GeV/c CMS data at 900 GeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle jet (chgjet#1) for charged particles with pT > 0.5 GeV/c and |η η| < 2.0. The data are corrected and compared with PYTHIA Tune Z1 at the generator level. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 100 150 200 250 300 PT(chgjet#1 or jet#1) GeV/c CDF data at 1.96 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading calorimeter jet (jet#1) for charged particles with pT > 0.5 GeV/c and |η η| < 1.0. The data are corrected and compared with PYTHIA Tune Z1 at the generator level. Rick Field – Florida/CDF/CMS Page 20 PYTHIA Tune Z1 "Transverse" Charged Particle Density: dN/dη ηdφ φ "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.2 1.5 RDF Preliminary data corrected pyZ1 generator level Charged Particle Density Charged Particle Density RDF Preliminary CMS 7 TeV 1.0 CDF 1.96 TeV 0.5 CMS 900 GeV Tune Z1 0.8 CDF 1.96 TeV 0.4 Tune Z1 0.0 0 20 40 60 80 100 0 20 PT(chgjet#1 or jet#1) GeV/c 40 60 80 100 PT(lepton-pair) GeV/c "Away" Charged Particle Density: dN/dη ηdφ φ "Transverse" Charged Particle Density: dN/dη ηdφ φ 3.0 1.6 7 TeV data corrected pyZ1 generator level 1.2 RDF Preliminary What about Min-Bias? Chgjet Production Charged Particle Density CMS Preliminary Charged Particle Density Charged Particles (PT>0.5 GeV/c) Drell-Yan Production Charged Particles (PT>0.5 GeV/c) 0.0 CMS 7 TeV data corrected pyZ1 generator level 0.8 Drell-Yan Production 0.4 Tune Z1 data corrected pyZ1 generator level CDF 1.96 TeV 2.0 CMS 7 TeV 1.0 Tune Z1 Drell-Yan Production Charged Particles (|η η|<2.0, PT>0.5 GeV/c) Charged Particles (PT>0.5 GeV/c) 0.0 0.0 0 10 20 30 40 50 60 70 80 90 100 0 40 60 80 100 PT(lepton-pair) GeV/c PT(chgjet#1) or PT(lepton-pair) GeV/c CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 20 Rick Field – Florida/CDF/CMS Page 21 PYTHIA Tune Z1 "Transverse" Charged Particle Density: dN/dη ηdφ φ "Transverse" Charged Particle Density: dN/dη ηdφ φ 1.2 1.5 RDF Preliminary data corrected pyZ1 generator level Charged Particle Density Charged Particle Density RDF Preliminary CMS 7 TeV 1.0 CDF 1.96 TeV 0.5 CMS 900 GeV Tune Z1 0.8 CDF 1.96 TeV 0.4 Tune Z1 Charged Particles (PT>0.5 GeV/c) Drell-Yan Production Overall amazingly good agreement 0.0 0.0 0 20 40 60 100 and Tevatron with80the LHC 0 20 40 60 80 PT(chgjet#1 or jet#1) GeV/c PT(lepton-pair) GeV/c Jet production and Drell-Yan! "Transverse" Charged Particle Density:(although dN/dη ηdφ φ not perfect "Away" yet) Charged Particle Density: dN/dηηdφφ 3.0 1.6 RDF Preliminary CMS Preliminary What about Min-Bias? Chgjet Production 7 TeV CDF 1.96 TeV Charged Particles (PT>0.5 GeV/c) data corrected pyZ1 generator level 1.2 Charged Particle Density Charged Particle Density CMS 7 TeV data corrected pyZ1 generator level 0.8 Drell-Yan Production 0.4 Tune Z1 100 data corrected pyZ1 generator level 2.0 CMS 7 TeV 1.0 Tune Z1 Drell-Yan Production Charged Particles (|η η|<2.0, PT>0.5 GeV/c) Charged Particles (PT>0.5 GeV/c) 0.0 0.0 0 10 20 30 40 50 60 70 80 90 100 0 40 60 80 100 PT(lepton-pair) GeV/c PT(chgjet#1) or PT(lepton-pair) GeV/c CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 20 Rick Field – Florida/CDF/CMS Page 22 The Inelastic Non-Diffractive Cross-Section Occasionally one of the parton-parton collisions is hard (pT > ≈2 GeV/c) Proton Proton Majority of “minbias” events! Proton “Semi-hard” partonparton collision (pT < ≈2 GeV/c) Proton + Proton + Proton Proton Proton + Proton Proton +… Multiple-parton interactions (MPI)! CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 23 The “Underlying Event” Select inelastic non-diffractive events that contain a hard scattering Proton Hard parton-parton collisions is hard (pT > ≈2 GeV/c) Proton 1/(pT)4→ 1/(pT2+pT02)2 The “underlying-event” (UE)! Proton Given that you have one hard scattering it is more probable to have MPI! Hence, the UE has more activity than “min-bias”. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Proton + + Proton Proton Rick Field – Florida/CDF/CMS “Semi-hard” partonparton collision (pT < ≈2 GeV/c) Proton Proton +… Multiple-parton interactions (MPI)! Page 24 Allow leading hard scattering to go to zero pT with same cut-off as the MPI! Model of σND Proton Proton Proton Proton Proton + Proton “Semi-hard” partonparton collision (pT < ≈2 GeV/c) 1/(pT)4→ 1/(pT2+pT02)2 Model of the inelastic nondiffractive cross section! + Proton Proton Proton + Proton Proton +… Multiple-parton interactions (MPI)! CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 25 UE Tunes Allow primary hard-scattering to go to pT = 0 with same cut-off! “Underlying Event” Fit the “underlying event” in a hard scattering process. Proton Proton 1/(pT)4→ 1/(pT2+pT02)2 “Min-Bias” “Min-Bias” (add (ND)single & double diffraction) Proton Predict MB (ND)! Proton + + Proton Proton Proton Single Diffraction Predict MB (IN)! +… CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Proton + Proton Proton Double Diffraction M2 M Rick Field – Florida/CDF/CMS M1 Page 26 Min-Bias Collisions Charged Particle Density: dN/dη η Charged Particle Density: dN/dη η 6 CMS Data ALICE Data PYTHIA Tune Z1 PYTHIA Tune Z1 Charged Particle Density Charged Particle Density 8 6 NSD = ND + DD 4 Tune Z1 CMS 2 pyZ1 ND = dashed pyZ1 NSD = solid 7 TeV NSD (all pT) 4 2 Tune Z1 INEL (all pT) 0 ALICE INEL = NSD + SD pyZ1 NSD = dashed pyZ1 INEL = solid 900 GeV 0 -4 -3 -2 -1 0 1 2 3 4 -4 -3 -2 Pseudo-Rapidity η -1 0 1 2 3 Pseudo-Rapidity η CMS NSD data on the charged particle rapidity distribution at 7 TeV compared with PYTHIA Tune Z1. The plot shows the average number of particles per NSD collision per unit η, (1/NNSD) dN/dη η. ALICE NSD data on the charged particle rapidity distribution at 900 GeV compared with PYTHIA Tune Z1. The plot shows the average number of particles per INEL collision per unit η, (1/NINEL) dN/dη η. “Minimum Bias” Collisions Proton CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Proton Rick Field – Florida/CDF/CMS Page 27 4 Min-Bias Collisions Charged Particle Density: dN/dη η Charged Particle Density: dN/dη η 6 CMS Data ALICE Data PYTHIA Tune Z1 PYTHIA Tune Z1 Charged Particle Density Charged Particle Density 8 6 NSD = ND + DD 4 Tune Z1 CMS 2 pyZ1 ND = dashed pyZ1 NSD = solid 7 TeV NSD (all pT) 4 2 Tune Z1 INEL (all pT) 0 ALICE INEL = NSD + SD pyZ1 NSD = dashed pyZ1 INEL = solid 900 GeV 0 -4 -3 -2 -1 0 1 2 3 4 -4 -3 Pseudo-Rapidity η -2 -1 0 1 2 3 Pseudo-Rapidity η CMS NSD data on the charged particle rapidity distribution at 7 TeV compared with PYTHIA Tune Z1. The plot shows the average number of particles per NSD collision per unit η, (1/NNSD) dN/dη η. ALICE NSD data on the charged particle rapidity distribution at 900 GeV compared with PYTHIA Tune Z1. The plot shows the average number of particles per INEL collision per unit η, (1/NINEL) dN/dη η. “Minimum Bias” Collisions Okay not perfect, but remember Proton we know that SD and DD are not modeled well! Proton CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 28 4 MB versus UE Divide be 2π π Charged Particle Density: dN/dη η 2.5 8 CMS Data CMS Data PYTHIA Tune Z1 PYTHIA Tune Z1 Charged Particle Density Charged Particle Density Charged Particle Density: dN/dη ηdφ φ 6 NSD = ND + DD 4 Tune Z1 CMS 2 pyZ1 ND = dashed pyZ1 NSD = solid 7 TeV NSD (all pT) 2.0 1.5 1.0 0.5 pyZ1 ND = dashed 7 TeV NSD (all pT) pyZ1 NSD = solid 0.0 0 -4 -3 -2 -1 0 1 2 3 4 -4 -3 -2 -1 0 1 2 3 4 Pseudo-Rapidity η Pseudo-Rapidity η CMS NSD data on the charged particle CMS NSD data on the charged particle rapidity rapidity distribution at 7 TeV compared distribution at 7 TeV compared with PYTHIA with PYTHIA Tune Z1. The plot shows Tune Z1. The plot shows the average number of the average number of charged particles charged particles per NSD collision per unit η−φ, per NSD collision per unit η, (1/NNSD) (1/NNSD) dN/dη ηdφ φ. dN/dη η. “Minimum Bias” Collisions Proton CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Proton Rick Field – Florida/CDF/CMS Page 29 MB versus UE Charged Particle Density: dN/dη ηdφ φ ηdφ φ Transverse Charged Particle Density: dN/dη 2.5 RDF Preliminary CMS Data PYTHIA Tune Z1 PYTHIA Tune Z1 Charged Particle Density Charged Particle Density 2.5 2.0 Factor of 2! 1.5 1.0 Charged Particles (|η η| < 2, all pT) 0.5 Tune Z1 CMS 2.0 Tune Z1 1.0 0.5 7 TeV ND pyZ1 ND = dashed 7 TeV NSD (all pT) 0.0 NSD = ND + DD 1.5 pyZ1 NSD = solid 0.0 0 5 10 15 20 25 -4 -3 -2 -1 0 1 2 3 Pseudo-Rapidity η PT max (GeV/c) Shows the density of charged particles in the “transverse” region as a function of PTmax for charged particles (All pT, |η η| < 2) at 7 TeV from PYTHIA Tune Z1. Outgoing Parton CMS NSD data on the charged particle rapidity distribution at 7 TeV compared with PYTHIA Tune Z1. The plot shows the average number of charged particles per NSD collision per unit η−φ, (1/NNSD) dN/dη ηdφ φ. PT(hard) “Minimum Bias” Collisions Initial-State Radiation Proton Proton Underlying Event Outgoing Parton Proton Underlying Event Proton Final-State Radiation CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 4 Rick Field – Florida/CDF/CMS Page 30 MB versus UE Charged Particle Density: dN/dη ηdφ φ ηdφ φ "Transverse" Charged Particle Density: dN/dη 2.5 CMS Data ATLAS 2.0 Charged Particle Density "Transverse" Charged Density 2.5 Factor of 2! 1.5 RDF Preliminary 1.0 ATLAS corrected data Tune Z1 generator level 0.5 Charged Particles (pT > 0.1 GeV/c, |η η|<2.5) 7 TeV CMS PYTHIA Tune Z1 2.0 Tune Z1 1.0 0.5 pyZ1 ND = dashed 7 TeV NSD (all pT) 0.0 NSD = ND + DD 1.5 pyZ1 NSD = solid 0.0 0 2 4 6 8 10 12 14 16 18 20 -4 -3 PTmax (GeV/c) -2 -1 0 1 2 3 Pseudo-Rapidity η ATLAS data on the density of charged particles in the “transverse” region as a function of PTmax for charged particles (pT > 0.1 GeV/c, |η η| < 2.5) at 7 TeV compared with PYTHIA Tune Z1. Outgoing Parton CMS NSD data on the charged particle rapidity distribution at 7 TeV compared with PYTHIA Tune Z1. The plot shows the average number of charged particles per NSD collision per unit η−φ, (1/NNSD) dN/dη ηdφ φ. PT(hard) “Minimum Bias” Collisions Initial-State Radiation Proton Proton Underlying Event Outgoing Parton Proton Underlying Event Proton Final-State Radiation CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 4 Rick Field – Florida/CDF/CMS Page 31 NSD Multiplicity Distribution Charged Multiplicity Distribution 1.0E-01 RDF Preliminary data CMS NSD pyZ1 generator level Difficult to produce enough events with large multiplicity! CMS Probability 1.0E-02 7 TeV 900 GeV 1.0E-03 Charged Particles (all PT, |η η|<2.0) Tune Z1 1.0E-04 0 20 40 60 80 100 Number of Charged Particles Generator level charged multiplicity distribution (all pT, |η η| < 2) at 900 GeV and 7 TeV. Shows the NSD = HC + DD prediction for Tune Z1. Also shows the CMS NSD data. “Minumum Bias” Collisions Proton CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Proton Rick Field – Florida/CDF/CMS Page 32 NSD Multiplicity Distribution Charged Multiplicity Distribution 1.0E-01 RDF Preliminary data CMS NSD pyZ1 generator level Difficult to produce enough events with large multiplicity! CMS Probability 1.0E-02 7 TeV 900 GeV 1.0E-03 Charged Particles (all PT, |η η|<2.0) Tune Z1 1.0E-04 0 20 40 60 80 100 Number of Charged Particles Generator level charged multiplicity distribution (all pT, |η η| < 2) at 900 GeV and 7 TeV. Shows the NSD = HC + DD prediction for Tune Z1. Also shows the CMS NSD data. “Minumum Bias” Collisions Proton CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Okay not perfect! But not that bad! Rick Field – Florida/CDF/CMS Proton Page 33 MB & UE "Transverse" Charged Particle Multiplicity Charged Multiplicity Distribution 1.0E+00 1.0E-01 RDF Preliminary “Min-Bias” “Underlying Event” data CMS NSD pyZ1 generator level Data Corrected Tune Z1 generator level 1.0E-01 CMS PT(chgjet#1) > 3 GeV/c Probability Probability 1.0E-02 7 TeV 900 GeV 1.0E-03 1.0E-02 900 GeV 7 TeV CMS 1.0E-03 1.0E-04 Charged Particles (all PT, |η η|<2.0) CMS Preliminary Tune Z1 Tune Z1 Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 1.0E-04 1.0E-05 0 20 40 60 80 100 0 Number of Charged Particles 5 10 15 20 25 30 35 Number of Charged Particles CMS corrected data at 900 GeV and 7 Generator level charged multiplicity TeV on the charged particle multiplicity distribution (all pT, |η η| < 2) at 900 GeV distribution in the “transverse” region for and 7 TeV. Shows the NSD = HC + DD η| < 2) charged particles (pT > 0.5 GeV/c, |η prediction for Tune Z1. Also shows the as defined by the leading charged particle CMS NSD data. jet with PT(chgjet#1) > 3 GeV/c compared with PYTHIA Tune Z1 at the generator level. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 34 MB & UE "Transverse" Charged Particle Multiplicity Charged Multiplicity Distribution 1.0E+00 1.0E-01 “Min-Bias” RDF Preliminary “Underlying Event” data CMS NSD pyZ1 generator level Data Corrected Tune Z1 generator level 1.0E-01 CMS PT(chgjet#1) > 3 GeV/c Probability Probability 1.0E-02 7 TeV 900 GeV 1.0E-03 1.0E-02 900 GeV 1.0E-04 0 20 CMS Tune Z1 Tune Z1 Difficult to produce 40 60 80 enough events with Number of Charged Particles large multiplicity! 7 TeV 1.0E-03 1.0E-04 Charged Particles (all PT, |η η|<2.0) CMS Preliminary Charged Particles (|η η|<2.0, PT>0.5 GeV/c) 1.0E-05 100 0 5 10 15 20 25 30 35 Number of Charged Particles Difficult to produce CMS corrected data at 900 GeV and 7 Generator level charged multiplicity enough events with TeV on the charged particle multiplicity distribution (all pT, |η η| < 2) at 900 GeV large “transverse” distribution in the “transverse” region for and 7 TeV. Shows the NSD = HC + DD multiplicity at low η| < 2) charged particles (pT > 0.5 GeV/c, |η prediction for Tune Z1. Also shows the hard scale! as defined by the leading charged particle CMS NSD data. jet with PT(chgjet#1) > 3 GeV/c compared with PYTHIA Tune Z1 at the generator level. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 35 Pile-Up at the LHC Charged Particle Multiplicity Distribution Charged Particle PseuoRapidity Distribution 4 Generator Level HCMB 14 TeV 0.04 Charged Particles (|η η|<2.0, all pT) Mean = 24.39 0.03 Generator Level HCMB 14 TeV pyDWT <Nchg> = 81.7 <Nchg> in 0.4 bin Probability per 1 Particle 0.05 pyDWT <Nchg> = 24.39 0.02 Npile = 1 3 2 1 0.01 Charged Particles (all pT) 0 0.00 0 10 20 30 40 50 60 70 80 90 100 -8 -6 -2 0 2 4 6 8 PseudoRapidity η Number of Charged Particles: Nchg Shows the charged multiplicity distribution (|η η| < 2, all pT) for Npile = 1 (i.e. shows, on the average, what one event looks like). The plot shows the probability of finding 0, 1, 2, … etc. charged particles. The sum of the points is equal to one. The mean is 24.39 charged particles and σ = 19.7. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 -4 Shows the charged particle pseudo-rapidity distribution (all pT) for Npile = 1 (i.e. shows, on the average, what one event looks like). The plot shows the <Nchg> in a 0.4 bin (i.e. not divided by bin size). The sum of the points with |η η| < 2 is 24.39. Rick Field – Florida/CDF/CMS Page 36 Pile-Up at the LHC Tune DWT “Hard-Core” No Trigger (cττ =10mm) Charged Particle Multiplicity Distribution Charged Particle PseuoRapidity Distribution 4 Generator Level HCMB 14 TeV 0.04 Charged Particles (|η η|<2.0, all pT) Mean = 24.39 0.03 Generator Level HCMB 14 TeV pyDWT <Nchg> = 81.7 <Nchg> in 0.4 bin Probability per 1 Particle 0.05 pyDWT <Nchg> = 24.39 0.02 Npile = 1 3 2 1 0.01 Charged Particles (all pT) 0 0.00 0 10 20 30 40 50 60 70 80 90 100 -8 -6 -2 0 2 4 6 8 PseudoRapidity η Number of Charged Particles: Nchg Shows the charged multiplicity distribution (|η η| < 2, all pT) for Npile = 1 (i.e. shows, on the average, what one event looks like). The plot shows the probability of finding 0, 1, 2, … etc. charged particles. The sum of the points is equal to one. The mean is 24.39 charged particles and σ = 19.7. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 -4 Shows the charged particle pseudo-rapidity distribution (all pT) for Npile = 1 (i.e. shows, on the average, what one event looks like). The plot shows the <Nchg> in a 0.4 bin (i.e. not divided by bin size). The sum of the points with |η η| < 2 is 24.39. Rick Field – Florida/CDF/CMS Page 37 Pile-Up at the LHC Charged Particle Multiplicity Distribution Charged Particle Multiplicity Distribution 0.16 Generator Level HCMB 14 TeV 0.06 Charged Particles (|η η|<2.0, all pT) pyDWT <Nchg> = 243.9 Mean = 243.9 0.04 Npile = 1 with Nchg->10*Nchg Npile = 10 0.02 0.00 Probability per 50 Particles Probability per 10 Particles 0.08 Generator Level HCMB 14 TeV 0.12 Charged Particles (|η η|<2.0, all pT) pyDWT <Nchg> = 1219.5 0.08 Npile = 10 with Nchg->5*Nchg Npile = 1 with Nchg->50*Nchg 0.04 Npile = 50 0.00 0 100 200 300 400 500 600 700 800 900 1000 0 500 Number of Charged Particles: Nchg 1000 1500 2000 2500 3000 3500 4000 4500 5000 Number of Charged Particles: Nchg Shows the charged multiplicity distribution Shows the charged multiplicity distribution (|η η| < 2, all pT) for Npile = 50 (i.e. shows, on (|η η| < 2, all pT) for Npile = 10 (i.e. shows, on the average, what 50 events looks like). The the average, what 10 events looks like). The plot shows the probability of finding 0, 50, plot shows the probability of finding 0, 10, 100, … etc. charged particles. The sum of the 20, … etc. charged particles. The sum of the points is equal to one. The mean is 1219.5 points is equal to one. The mean is 243.9 charged particles and σ = 138.9. Also shown charged particles and σ = 62.3. Also shown is the Npile = 1 distribution scaled by a factor is the Npile = 1 distribution scaled by a of 50 (i.e. Nchg → 50× ×Nchg) and the Npile = factor of 10 (i.e. Nchg → 10× ×Nchg). 10 distribution scaled by a factor of 5 (i.e. Nchg → 5× ×Nchg). CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 38 Pile-Up at the LHC Charged Particle Multiplicity Distribution “Central Limit Theorem”: ~ Npile, σDistribution ~ sqrt(Npile)! Charged<Nchg> Particle Multiplicity 0.16 Generator Level HCMB 14 TeV Duh! 0.06 Charged Particles (|η η|<2.0, all pT) pyDWT <Nchg> = 243.9 Mean = 243.9 0.04 Npile = 1 with Nchg->10*Nchg Npile = 10 0.02 0.00 Probability per 50 Particles Probability per 10 Particles 0.08 Generator Level HCMB 14 TeV 0.12 True for Particles any P(|η cut! Charged |<2.0, all pT) Tη(min) pyDWT <Nchg> = 1219.5 0.08 Npile = 10 with Nchg->5*Nchg Npile = 1 with Nchg->50*Nchg 0.04 Npile = 50 0.00 0 100 200 300 400 500 600 700 800 900 1000 0 500 Number of Charged Particles: Nchg 1000 1500 2000 2500 3000 3500 4000 4500 5000 Number of Charged Particles: Nchg Shows the charged multiplicity distribution Shows the charged multiplicity distribution (|η η| < 2, all pT) for Npile = 50 (i.e. shows, on (|η η| < 2, all pT) for Npile = 10 (i.e. shows, on the average, what 50 events looks like). The the average, what 10 events looks like). The plot shows the probability of finding 0, 50, plot shows the probability of finding 0, 10, 100, … etc. charged particles. The sum of the 20, … etc. charged particles. The sum of the points is equal to one. The mean is 1219.5 points is equal to one. The mean is 243.9 charged particles and σ = 138.9. Also shown charged particles and σ = 62.3. Also shown is the Npile = 1 distribution scaled by a factor is the Npile = 1 distribution scaled by a of 50 (i.e. Nchg → 50× ×Nchg) and the Npile = factor of 10 (i.e. Nchg → 10× ×Nchg). 10 distribution scaled by a factor of 5 (i.e. Nchg → 5× ×Nchg). CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 39 Tevatron Energy Scan Proton CDF 1 mile AntiProton Proton 900GeV GeV 300 1.96 TeV AntiProton Just before the shutdown of the Tevatron CDF has collected more than 10M “min-bias” events at several center-of-mass energies! 300 GeV 12.1M MB Events 900 GeV 54.3M MB Events CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 40 New CDF Energies ηdφ φ "Transverse" Charged Particle Density: dN/dη "Transverse" Charged Density 1.2 7 TeV ATLAS RDF Preliminary Tune Z1 generator level 0.8 900 GeV ATLAS 0.4 Tune Z1 Charged Particles (|η η|<0.8, PT>0.5 GeV/c) 0.0 0 5 10 15 20 25 30 35 PTmax (GeV/c) ATLAS preliminary data at 900 GeV and 7 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles η| < 0.8. The data are corrected and compared with PYTHIA with pT > 0.5 GeV/c and |η Tune Z1 at the generator level. Predictions for CDF on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 0.8 from PYTHIA Tune Z1 at the generator level. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 41 New CDF Energies "Transverse" Charged Particle Density: dN/dη ηηdφ φφ "Transverse" Charged Charged Density "Transverse" 1.2 7 TeV ATLAS RDF Preliminary Tune Z1 generator level 0.8 1.96 TeV CDF 900 GeV ATLAS 900 GeV CDF 0.4 300 GeV CDF Tune Z1 Charged Particles ηη|<0.8, Particles (|η (|η |<0.8, PT>0.5 PT>0.5 GeV/c) GeV/c) 0.0 0 5 10 15 20 20 25 25 30 30 35 35 PTmax (GeV/c) ATLAS preliminary data at 900 GeV and 7 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles η| < 0.8. The data are corrected and compared with PYTHIA with pT > 0.5 GeV/c and |η Tune Z1 at the generator level. Predictions for CDF on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 0.8 from PYTHIA Tune Z1 at the generator level. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 42 gmbsar Files = 273 Events = 66,374,130 Size = 803,837,367 KB "Transverse" Charged Particle Density: dN/dη ηdφ φ PTmax Direction ∆φ “Toward” “Transverse” “Transverse” “Away” "Transverse" Charged Density 1.0 CDF Preliminary Raw Data 1.96 TeV 900 GeV 0.5 300 GeV Bin Center Charged Particles (|η η|<1.0, PT>0.5 GeV/c) 0.0 0 5 10 15 20 25 30 35 PTmax (GeV/c) Raw CDF data at 300 GeV, 900 GeV, and 1.96 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 1.0. CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 43 gmbsar Files = 273 Events = 66,374,130 Size = 803,837,367 KB 1.96 TeV 1 and only 1 Q12 Vertex P0-5 19,420,876 Events 900 GeV 0 or 1 Q12 Vertex 38,306,169 Events "Transverse" Charged Particle Density: dN/dη ηdφ φ PTmax Direction ∆φ “Toward” “Transverse” “Transverse” “Away” "Transverse" Charged Density 1.0 CDF Preliminary Raw Data 1.96 TeV 900 GeV 0.5 300 GeV Bin Center Charged Particles (|η η|<1.0, PT>0.5 GeV/c) 0.0 0 5 10 15 20 25 30 35 PTmax (GeV/c) Raw CDF data at 300 GeV, 900 GeV, and 1.96 TeV on the “transverse” charged particle density, dN/dη ηdφ φ, as defined by the leading charged particle (PTmax) for charged particles with pT > 0.5 GeV/c and |η η| < 1.0. 300 GeV 0 or 1 Q12 Vertex 7,484,514 Events CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS Page 44 How Universal are the Tunes? Do we need a separate tune for each center-of-mass energy? Outgoing Parton PT(hard) 900 GeV, 1.96 TeV, 7 TeV, etc. Initial-State Radiation Proton PYTHIA Tune DW did a nice (although not perfect) job predicting the LHC Jet Production and Drell-Yan UE data. I am still hoping for a single tune that will describe all energies! Tune Z1 also very good! Proton Underlying Event Underlying Event Outgoing Parton Final-State Radiation Outgoing Parton PT(hard) Initial-State Radiation Proton Soon we will have UE data at 300 GeV, 900 GeV, 1.96 TeV, 7 TeV, & 8 TeV and can map out the energy dependence! Proton Underlying Event Underlying Event Outgoing Parton Do we need a separate tune for each hard QCD Final-State Radiation Color subprocess? Jet Production, Drell-Yan Production, etc. The same tune can describe both Jet Production and Drell-Yan! Do we need separate tunes for “Min-Bias” (MB) and the “underlying event” (UE) in a hard scattering process? PHTHIA Tune Z1 does fairly well at both the UE and MB, but you cannot expect such a naïve approach to be perfect! CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS ) P(90 R A P Connections “Minimum Bias” Collisions Proton Proton PA RP (82 ) Diffraction Page 45 How Universal are the Tunes? Do we need a separate tune for each center-of-mass energy? Outgoing Parton PT(hard) 900 GeV, 1.96 TeV, 7 TeV, etc. Initial-State Radiation Proton PYTHIA Tune DW did a nice (although not perfect) job predicting the LHC Jet Production and Drell-Yan UE data. I am still hoping for a single tune that will describe all energies! Tune Z1 also very good! Proton Underlying Event Underlying Event Outgoing Parton Final-State Radiation What we are learning should Soon we will have UE data at 300 GeV, 900 1.96 TeV, allow forGeV, more precise 7 TeV, & 8 TeV and can map out the energy dependence! predictions at future LHC energies Do we need a separate tune for each QCD13 TeV)! (10hard TeV, Outgoing Parton PT(hard) Initial-State Radiation Proton Proton Underlying Event Outgoing Parton Underlying Event Final-State Radiation Color subprocess? Jet Production, Drell-Yan Production, etc. The same tune can describe both Jet Production and Drell-Yan! Do we need separate tunes for “Min-Bias” (MB) and the “underlying event” (UE) in a hard scattering process? PHTHIA Tune Z1 does fairly well at both the UE and MB, but you cannot expect such a naïve approach to be perfect! CMS High Luminosity Workshop Alushta, Ukraine, May 29, 2012 Rick Field – Florida/CDF/CMS ) P(90 R A P Connections “Minimum Bias” Collisions Proton Proton PA RP (82 ) Diffraction Page 46
