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VBF H->  in CMS at LHC

VBF H->  in CMS at LHC. Jessica Leonard University of Wisconsin - Madison Preliminary Examination. Outline. Motivation for Higgs Higgs Physics The Higgs ->   Signal The Large Hadron Collider The Compact Muon Solenoid Detector Monte Carlo Event Selection Simulation Results

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VBF H->  in CMS at LHC

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  1. VBF H-> in CMS at LHC Jessica Leonard University of Wisconsin - Madison Preliminary Examination

  2. Outline • Motivation for Higgs • Higgs Physics • The Higgs ->  Signal • The Large Hadron Collider • The Compact Muon Solenoid Detector • Monte Carlo • Event Selection • Simulation Results • Future Plans

  3. Standard model • One particle we haven’t seen yet: Higgs! • Gives mass to W, Z • Higgs coupling strength determines masses of other massive particles • Standard Model depends on Higgs!

  4. Higgs Physics • More info on Why We Need the Higgs?? Talk about: Higgs required to give mass to W and Z, also couples with most other particles -- coupling strength determines masses of those particles

  5. General Higgs Production • Gluon-gluon fusion high rate, but high QCD background • Vector boson fusion lower rate, but lower background

  6. Higgs decays • Low Higgs mass: • Bb~ most prominent signal below ~100 GeV, tau is second • Tau jets easier to identify than b jets • Higher Higgs mass: • WW most prominent decay • ZZ second

  7. Vector Boson Fusion to   • H-> • Relatively high rate for low-mass Higgs • Distinct signal • VBF • Relatively high rate • Identification of Higgs production via quark products in final state • qqH->: Good potential for discovery!

  8. Large Hadron Collider • 27-kilometer ring near Geneva, Switzerland • Proton-proton collisions • Center of mass energy 14 TeV • Design luminosity 1034 cm-2 s-1 • Physics in 2008

  9. LHC Magnets • Superconducting NbTi magnets require T = 1.9K • 1232 dipoles bend proton beam around ring, B = 8T • Quadrupoles focus beam

  10. LHC Startup Stage 1 Initial commissioning 43x43156x156, 3x1010/bunch L=3x1028 - 2x1031 Starts in 2008 Shutdown • Year one (+) operation • Lower intensity/luminosity: • Event pileup • Electron cloud effects • Phase 1 collimators • Equipment restrictions • Partial Beam Dump • 75 ns. bunch spacing (pileup) • Relaxed squeeze Stage 2 75 ns operation 936x936, 3-4x1010/bunch L=1032 - 4x1032 Stage 3 25 ns operation 2808x2808,3-5x1010/bunch L=7x1032 - 2x1033 Long Shutdown Phase 2 collimation Full Beam Dump Scrubbed Full Squeeze Stage 4 25 ns operation Push to nominal per bunch L=1034

  11. Experiments at the LHC ATLAS and CMS : pp, general purpose

  12. Compact Muon Solenoid (CMS) CALORIMETERS HCAL ECAL Plastic scintillator/brass sandwich 76k scintillating PbWO4 crystals IRON YOKE MUON ENDCAPS Cathode StripChambers (CSC) Resistive PlateChambers (RPC) TRACKER PixelsSilicon Microstrips 210 m2 of silicon sensors 9.6M channels Weight: 12,500 T Diameter: 15.0 m Length: 21.5 m Superconducting Coil,4 Tesla MUON BARREL Resistive Plate Drift Tube Chambers (RPC) Chambers (DT)

  13. Tracker Tracker coverage extends to ||<2.5, with maximum analyzing power in ||<1.6 Silicon pixel detectors used closest to the interaction region Silicon strip detector used in barrel and endcaps

  14. ECAL • >80,000 PbWO4 crystals • high density • small Moliere radius (2.19 cm) • radiation resistant • Precise measurements of electron/photon energy and position • Each crystal 22mm x 22mm •  x  = 0.0175 x 0.0175 barrel, increases to 0.05 x 0.05 in endcap • Covers || < 3 • Resolution:

  15. Electromagnetic Calorimeter • ECAL measures e/ energy and position to || < 3 • 80,000+ lead tungstate (PbWO4) crystals • High density • Small Moliere radius (2.19 cm) compares to 2.2 cm crystal size • Resolution:

  16. HCAL • HCAL sampling calorimeter (barrel, endcap) • 50 mm copper plates and 4 mm scintillator tiles • Measures energies and positions of central jets • Covers || < 3 • Energy resolution: • HF extends coverage to || = 5 • Steel plates and 300 m quartz fibers - withstand high radiation • Measures energies and positions of forward jets • Resolution:

  17. HCAL samples showers to measure their energy/position HB -- central region Brass/scintillator layers Eta coverage || < 3 Resolution: HF -- forward region Steel plates/quartz fibers Eta coverage to 5 Resolution: Hadronic Calorimeter

  18. Muon System • Muon chambers identify muons and provide position information for track matching. • Drift tube chambers max area 4m x 2.5m cover barrel to ||=1.3 • Cathode strip chambers in endcaps use wires and strips to measure r and , respectively. Coverage ||=0.9 to 2.4. • Resistive plate chambers capture avalanche charge on metal strips. Coverage ||<2.1

  19. Trigger

  20. Current CMS Progress • Many components being currently lowered into experimental cavern or already lowered -- including some worked on by Wisconsin.

  21. Seeing Particles in CMS Lead Tungstate Brass/Scintillator

  22. Finding the Higgs • Feynman diagram of higgs production with stuff coming out: H-> tau tau, taus decay hadr or lept -- get 4-pt interaction feynman diagram. Tag quarks: say “become jets -- see next slide”

  23. Produced Observed Jets and Hadronization • Colored partons produced in hard scatter → “Parton level” • Colorless hadrons form through fragmentation → “Hadron level” • Collimated “spray” of real particles → Jets • Particle showers observed as energy deposits in detectors → “Detector level”

  24. Calorimeter Trigger Geometry

  25. Level-1 Trigger • (as opposed to entire trigger on detector component slide) • What sort of stuff on this slide?

  26. Calorimeter Trig. Algorithms • Electron (Hit Tower + Max) • 2-tower ET + Hit tower H/E • Hit tower 2x5-crystal strips >90% ET in 5x5 (Fine Grain) • Isolated Electron (3x3 Tower) • Quiet neighbors: all towerspass Fine Grain & H/E • One group of 5 EM ET < Thr. • Jet or t ET • 12x12 trig. tower ET sliding in 4x4 steps w/central 4x4 ET > others • t: isolated narrow energy deposits • Energy spread outside t veto pattern sets veto • Jet  tif all 9 4x4 region t vetoes off

  27. Jet Finding: Cone Algorithm • Maximize total ET of hadrons in cone of fixed size • Procedure: • Construct seeds (starting positions for cone) • Move cone around until ET in cone is maximized • Determine the merging of overlapping cones • Issues: • Overlapping cones • Seed , Energy threshold • Infrared unsafe • σ divergesas seed threshold → 0 R

  28. Electron Reconstruction • Stuff from cal trigger slide -- just split that slide up? • Need other electron reconstruction stuff?

  29. Tau Reconstruction • Tau jet must be within narrow cone in calorimeter (Rs) • Jet must match track within cone of radius Rm • No other energy deposits may be in cone of radius Ri

  30. Monte Carlos • How do we know all our algorithms actually work? • Simulate the entire event, run it through the actual reconstruction. We know what the “right” answer is, so we can tell how well our reconstruction algorithms work.

  31. Parton Level Simulated by PYTHIA Hadron Level Model Fragmentation Model (PYTHIA) Detector Level Detector simulationbased on GEANT Monte Carlos (MCs) Parton Level Hadron Level Detector Simulation

  32. Lund String Fragmentation • Used by MCs (or just “PYTHIA”) to describe hadronization and jet formation. • Color “string" stretched between q and q moving apart • Confinement with linearly increasing potential (1GeV/fm) • String breaks to form 2 color singlet strings, and so on., until only on mass-shell hadrons remain.

  33.  decays in detector • Higgs decays isotropically, so signature in general is in central detector (as opposed to forward) •  -> W* + , then • W* -> lepton + l OR • W* -> u + dbar e.g., more hadronization possible (single- and triple-prong events) • What do these look like in the detector? • lepton + l : electron (ECAL energy + track) or muon (muon chamber energy + track) + missing energy • hadrons : hadronic jet (HCAL energy + odd number of tracks), energy deposit must be small and contiguous --> tagged as “ jet”

  34. Event Selection • Startes with ~50,000 H-> events; no constraints on  decays. Higgs mass set to 130 GeV. • Cuts from PTDR are slides 41-44 -- include all of them? (there are four slides’ worth!) Organized how? • PTDR cut summary table below (not all specifics included)

  35. Plots • From Physics TDR:

  36. What next?

  37. Conclusions

  38. Extras

  39. Tau decay • Tau decay Require a “narrow” jet in the calorimetry. Require confirmation from the tracking, and isolation around the narrow jet.

  40. H-> final states and triggers • Note: Here “jet” means energy deposit consistent with  • ->jj (NOT actually a final state in PTDR study) • L1: single or double  (93, 66 GeV) ??? • HLT: double  ??? • ->j • L1: single  • HLT: single ,  +  jet • ->ej • L1: single isolated e, e +  jet • HLT: single isolated e, e +  jet

  41. H->->l++single-prong event offline selection • e and  candidates identified • Additional electron requirements: • E/p > 0.9 • Tracker isolation • Hottest HCAL tower Et < 2 GeV • Highest-pt lepton candidate with pt > 15 GeV chosen • Lepton track identifies the other tracks of interest: within z = 0.2 cm at vertex

  42. H->->l++single-prong event offline selection (cont.) •  candidates identified; jet formed around each and passed through t-tagging requirements • Require -jet charge opposite lepton charge • Hottest HCAL tower Et > 2 GeV if  coincides with electron candidate • -jet Et > 30 GeV

  43. H->->l++single-prong event offline selection (cont.) • Jets are the 2 highest-Et jets with Et > 40 GeV, not including e and  candidate • Jets must be within || < 4.5, as well as having different signs in h • Require hj1j2 > 4.5, fj1j2 < 2.2, invariant mass Mj1j2 > 1 TeV • Require transverse mass of lepton-MisEt system < 40 GeV

  44. H->->2 1-prong • Backgrounds: ttbar, Drell-Yan Z/*, W+jet, Wt, QCD multi-jet

  45. H->->+jet

  46. H->->e+jet

  47. Back-up slides

  48. Dipole Magnet Field Diagram • Field Diagram

  49. ATLAS • ATLAS info

  50. ECAL crystal • ECAL lead tungstate crystal

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