1 / 38

David Anez Saint Mary ’ s/Dalhousie University December 10, 2012

E08-010: Measurement of the Coulomb quadrupole amplitude in the γ * p → Δ (1232) reaction in the low momentum transfer region. David Anez Saint Mary ’ s/Dalhousie University December 10, 2012. Introduction. Took measurements of the p ( e , e ′ p ) π 0 (pion electroproduction) reaction

chaeli
Télécharger la présentation

David Anez Saint Mary ’ s/Dalhousie University December 10, 2012

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. E08-010: Measurement of the Coulomb quadrupole amplitude in the γ*p→Δ(1232) reaction in the low momentum transfer region David Anez Saint Mary’s/Dalhousie University December 10, 2012

  2. Introduction • Took measurements of the p(e,e′p)π0 (pion electroproduction) reaction • In the low Q2 region where the pion cloud is expected to dominate • With center-of-mass energies near the Δ resonance to look at the transition amplitudes between the nucleon and the delta • To better understand the Coulomb quadrupole transition amplitude behavior in this region and how it affects nucleon deformation David Anez - December 10, 2012 2/30

  3. Motivation: Constituent Quark Model • Wave functions created David Anez - December 10, 2012 3/30

  4. Motivation: Constituent Quark Model • Magnetic Dipole (M1 / ) • Spin-flip • Dominant David Anez - December 10, 2012 4/30

  5. Motivation: Constituent Quark Model • Electric quadrupole (E2 / ) • Coulomb quadrupole (C2 / ) • Only with virtual photons David Anez - December 10, 2012 5/30

  6. Multipole Amplitudes David Anez - December 10, 2012 6/30

  7. Multipole Amplitudes E1+ and S1+ at same magnitude as background amplitudes Measure ratio to dominant M1+ EMR = CMR = David Anez - December 10, 2012 7/30

  8. World Data and Models David Anez - December 10, 2012 8/30

  9. World Data and Models David Anez - December 10, 2012 9/30

  10. World Data and Models Q2 = 0.045 (GeV/c)2 New lowest CMR value θe = 12.5° Q2 = 0.125 (GeV/c)2 Validate previous measurements Q2 = 0.090 (GeV/c)2 Bridge previous measurements David Anez - December 10, 2012 10/30

  11. Response Functions Unpolarized cross section made up of four independent partial cross sections David Anez - December 10, 2012 11/30

  12. Response Functions David Anez - December 10, 2012 12/30

  13. Response Functions Truncated Multipole Expansion Model Dependent Extraction Fit theoretical model to existing data Insert model values for background amplitudes David Anez - December 10, 2012 13/30

  14. The Experiment • Jefferson Lab, Hall A • Feb 27th – Mar 8th, 2011 • 1160 MeV e− beam • 4 & 15 cm LH2 target • Two high resolution spectrometers • HRSe and HRSh David Anez - December 10, 2012 14/30

  15. High Resolution Spectrometers • Vertical drift chambers • Particle tracking • Scintillators • Timing information • Triggering DAQ • Gas Cerenkov detectors • Particle identification • Lead glass showers • Particle identification David Anez - December 10, 2012 15/30

  16. Original Kinematic Settings David Anez - December 10, 2012 16/30

  17. Revised Kinematic Settings David Anez - December 10, 2012 17/30

  18. Actual Kinematic Settings 85% 85% David Anez - December 10, 2012 18/30

  19. Calibrations – Beam Current • BCM Calibration Runs • Kinematic 2, March 3rd • 80 µA to 0.2 µA • CODA Run 2252, MCC Run 170 • Match Faraday Cup Current to OLO2 Current • CODA Run 2254, MCC Run 173 • Match BCM Voltages to OLO2 Current • Bypassed Unser Coil David Anez - December 10, 2012 19/30

  20. Calibrations – Beam Position • BPM Calibration Runs • Feb 19th – Runs 1579-1599 • May 4th – Runs 4139-4149 • BPM Code • Determine pedestals • Measure means • Calculate coefficients • Check calculations • Determine raster constants David Anez - December 10, 2012 20/30

  21. Calibrations – Boiling Test • Boiling Test Runs • Kinematic 12, Mar 6th • Runs 2439-2447 • 10 µA to 80 µA, 4cm target • HAPPEX Luminosity Scintillators • Downstream of target David Anez - December 10, 2012 21/30

  22. Calibrations – Vertical Drift Chambers • VDC Code • Find maximum • Find largest slope David Anez - December 10, 2012 22/30

  23. Calibrations – Mispointing • Target and Optical Survey • JLab Alignment Group • Feb 11th • BeO Target Runs • Each kinematic David Anez - December 10, 2012 23/30

  24. Calibrations – RHRS Gas Cerenkov Particle Identification – Electrons David Anez - December 10, 2012 24/30

  25. Calibrations – LHRS Pion Rejector Particle Identification – Protons David Anez - December 10, 2012 25/30

  26. Calibrations – RHRS Shower/Preshower Particle Identification – Electrons David Anez - December 10, 2012 26/30

  27. Coincidence Timing Online Analysis Difference of BB T3 & T1 Offline Analysis Difference of LHRS T3 & T1 S2m Timing Difference David Anez - December 10, 2012 27/30

  28. Coincidence Timing • LHRS Double Peak Problem • Due to S1 miswiring • RHRS Double Peak Problem • Due to S2 miswiring • Both solved by subtracting local T1 David Anez - December 10, 2012 28/30

  29. Coincidence Timing • Red: No other corrections, shifted +80 ns • Green: Pathlength corrections • Blue: Pathlength corrections and calibration offsets David Anez - December 10, 2012 29/30

  30. Still To Do • Cut Determination • Process Raw Data • Calculate Efficiencies • Calculate Systematic Errors • Produce Simulation Data • Extract Cross Sections • Thesis – Summer 2013 • Paper – Summer 2013 David Anez - December 10, 2012 30/30

  31. Motivation: Constituent Quark Model • One-body interactions • Two-body interactions

  32. Motivation: Constituent Quark Model • Pion Cloud

  33. Kinematics – Electronic Vertex • Incoming electron • Energy E • Momentum ki • Scattered electron • Energy E′ • Momentum kf • Angle θe • Virtual photon • Energy ω • Momentum q • Angle θq

  34. Kinematics – Electronic Vertex • Momentum transfer, Q2

  35. Kinematics – Hadronic Vertex • Recoil proton • Energy Ep • Momentum pp • Angle θpq • Recoil pion • Energy Eπ • Momentum pπ • Angle θπ • Not detected

  36. Kinematics – Planes • Scattering plane – ki and kf • Recoil plane – pp and pπ • Azimuthal angle – pq

  37. Multipole Amplitudes • General form of πN Multipoles: • X – type of excitation (M, E, S) • I – isospin of excited intermediate state • ℓ± – JΔ = ℓ ± 1⁄2 • Magnetic dipole – M1 / • Electric quadrupole – E2 / • Coulomb quadrupole – C2 /

  38. Response Functions • Unpolarized cross section made up of four independent partial cross sections

More Related