1 / 18

Elastic Scattering and Diffraction at D Ø

Elastic Scattering and Diffraction at D Ø. Tamsin Edwards for the D Ø collaboration 14 th - 18 th April, 2004 XII International Workshop on Deep Inelastic Scattering, Š trbsk é Pleso, Slovakia. About 40% of the total pp cross-section is elastic scattering and diffraction.

lona
Download Presentation

Elastic Scattering and Diffraction at D Ø

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Elastic Scattering andDiffraction at DØ Tamsin Edwards for the DØ collaboration 14th - 18th April, 2004 XII International Workshop on Deep Inelastic Scattering, Štrbské Pleso, Slovakia

  2. About 40% of the total pp cross-section is elastic scattering and diffraction • experimental signatures: • rapidity gap - absence of particles or energy above threshold in some region of rapidity in the detector • intact proton - p or p scattered at small angle from the beam Colour singlet exchange • The Tevatron collides protons and antiprotons at √s = 1.96 TeV at an average rate of 1.7 MHz • Elastic and diffractive processes involve the exchange of a colour singlet • Colour singlet exchange • Quantum numbers of the vacuum: • no charge • no colour • often referred to as Pomeron exchange

  3. either p or p intact • p and p intact, with no momentum loss • no other particles produced Searches for colour singlet exchange • Two types of analysis discussed in this talk: • Single Diffraction • search for rapidity gap in forward regions of DØ • Luminosity Monitor • Calorimeter rapidity gap • Elastic Scattering proton track • search for intact protons in beam pipe • Forward Proton Detector proton track

  4. South (η>0) North (η<0) p p Luminosity Monitor Luminosity Monitor (LM) • Scintillating detector • 2.7 < |η| < 4.4 • Charge from wedges on one side are summed: Detector is on/off on each side, North and South

  5. Calorimeter Liquid argon/uranium calorimeter Cells arranged in layers: • electromagnetic (EM) • fine hadronic (FH) • coarse hadronic (CH) • Sum E of Cells in EM and FH layers above threshold: EEM > 100 MeV EFH > 200 MeV 2.7 LM range 4.4 2.6 Esum range 4.1 - 5.3 LM EM CH FH

  6. Calorimeter energy sum • Use energy sum to distinguish proton break-up from empty calorimeter: Log(energy sum) on North side: Areas are normalised to 1 empty events physics samples 10 GeV • Esum cut of 10GeV was chosen for current study • Final value will be optimised using full data sample • Compare 'empty event' sample with physics samples: • Empty event sample: random trigger. Veto LM signals and primary vertex, i.e. mostly empty bunch crossings • Physics samples: minimum bias (coincidence in LM), jet and Z→μμ events

  7. Efficiency and backgrounds Considerations to convert detector signal into physics: • Contamination from fake interactions • rapidity gap selection may favour non-physics events • Contamination from non-diffractive events • proton break-up not detected • acceptance • efficiency • Efficiency for diffractive events • gap filled by: • backscatter • beam losses • noise • pile-up effects • multiple interactions These studies are currently underway, and are required for a measurement of the ratio of diffractive to non-diffractive events

  8. DØ Run II preliminary Summer 2003 • RunI publication ”Observation of diffractively produced W and Z bosons in pp Collisions at sqrt(s)=1.8 TeV”, Phys. Lett. B 574, 169 (2003) Nine single diffractive Z→e+e- events. No result in muon channel. • RunII: first search for forward rapidity gaps in Z→μ+μ- events Search for diffractive Z→μμ • Inclusive Z→μμ sample well understood: • di-muon (|η|<2) or single muon (|η|< ~1.6) trigger • 2 muons, pT > 15GeV, opposite charge • at least one muon isolated in tracker and calorimeter • anti-cosmics cuts based on tracks: • displacement wrt beam • acolinearity of two tracks Mμμ (GeV)

  9. First step towards gap: LM only • Separate the Z sample into four groups according to LM on/off: • Expect worst cosmic ray contamination in sample with both sides of LM off • no evidence of overwhelming cosmics background in LM off samples WORK IN PROGRESS cosmics shape expected from inclusive sample

  10. 89.8 ± 0.1 GeV 89.6 ± 1.0 GeV 90.2 ± 1.3 GeV 89.3 ± 2.0 GeV Z Mass of rapidity gap candidates • Add Esum requirement: • Invariant mass confirms that these are all Drell-Yann/Z events • Will be able to compare Z boson kinematics (pT, pz, rapidity) WORK IN PROGRESS Gap North &Gap Southcombined

  11. Diffractive Z→μμ candidate outgoing proton side outgoing anti-proton side muon muon muon 11 muon

  12. Z→μμ with rapidity gaps: Summary • Preliminary definition of rapidity gap at DØ Run II • Study of Z→μ+μ- events with a rapidity gap signature (little or no energy detected in the forward direction) • Current status: • Evidence of Z events with a rapidity gap signature • Quantitative studies of gap definition, backgrounds, efficiency in progress (effects could be large) • No interpretation in terms of diffractive physics possible yet • Plans: • Measurement of the fraction of diffractively produced Z events • Diffractive W→μν, W/Z→electrons, jets and other channels • Use tracks from Forward Proton Detector 12

  13. Forward Proton Detector Forward Proton Detector (FPD) - a series of momentum spectrometers that make use of accelerator magnets in conjunction with position detectors along the beam line • Quadrupole Spectrometers • surround the beam: up, down, in, out • use quadrupole magnets (focus beam) • Dipole Spectrometer • inside the beam ring in the horizontal plane • use dipole magnet (bends beam) • also shown here: separators (bring beams together for collisions) A total of 9 spectrometers composed of 18 Roman Pots

  14. ξ = 1 - pLf/pLi t = (pf - pi)2 Forward Proton Detector Forward Proton Detector • scintillating fiber tracker • can be brought within a few millimetres of the beam • six layers to minimise ghost hits and reconstruction ambiguities • diagonal: U, U’ • opposite diagonal: V, V’ • vertical: X, X’ • trigger scintillator • primed layers offset from unprimed • read out by PMTs Reconstructed track is used to calculate kinematic variables of the scattered proton: t - four-momentum transfer ξ - the fraction of longitudinal momentum lost by the proton t ~ θ2, where θ is scattering angle where pi(f) = inital (final) momentum

  15. p P A2U A1U p p P1D P2D Elastic Scattering • Elastic scattering: ξ = 0 • Quadrupole acceptance: • t > 0.8 GeV2 (requires sufficient scattering angle to leave beam) • all ξ (no longitudinal momentum loss necessary) • Measure dN/dt for elastic scattering using preliminary and incomplete FPD: • antiproton side: • quadrupole ‘up’ spectrometer • trigger only • proton side: • quadrupole ‘down’ spectrometer • full detector read-out

  16. Preliminary Elastic Scattering Results ξdistribution

  17. Preliminary Elastic Scattering Results • The dσ/dt data collected by different experiments at different energies • A factor of 10-2 must be applied to each curve • New DØ dN/dt distribution has been normalized by E710 data • Compare slope with model: Block et al, Phys. Rev. D41, pp 978, 1990.

  18. Elastic Scattering & Diffraction: Summary • Study of Z→μ+μ- events with a rapidity gap signature • Evidence of Z events with a rapidity gap signature • Quantitative studies of gap definition, backgrounds, efficiency in progress • Proton-antiproton elastic scattering was measured by the DØ Forward Proton Detector • dN/dt was measured in the range 0.96 < |t| < 1.34 GeV2 • The future: study many diffractive physics channels using rapidity gaps and full Forward Proton Detector system

More Related