1 / 32

L/T separation in the 3 He(e,e’p) reaction at parallel kinematics Freija Descamps Supervisors:

L/T separation in the 3 He(e,e’p) reaction at parallel kinematics Freija Descamps Supervisors: Ron Gilman Eric Voutier Co-supervisor: Jean Mougey. L/T separation in the 3He(e,e’p) reaction at parallel kinematics. Motivations Quasi-elastic scattering 3 He(e,e’p) cross section

calla
Download Presentation

L/T separation in the 3 He(e,e’p) reaction at parallel kinematics Freija Descamps Supervisors:

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. L/T separation in the 3He(e,e’p) reaction at parallel kinematics Freija Descamps Supervisors: Ron Gilman Eric Voutier Co-supervisor: Jean Mougey

  2. L/T separation in the 3He(e,e’p) reactionat parallel kinematics • Motivations • Quasi-elastic scattering • 3He(e,e’p) cross section • L/T separation • Experimental setup • Cross section extraction • Experimental data • Normalization • Monte Carlo simulation • Results • L/T separation • Status report • Conclusion and prospects

  3. Motivations Change in structure? Free nucleon Bound nucleon Study bound nucleon by (e,e’p) quasi-elastic scattering Extract electromagnetic response functions for various transfered four-momenta Q (i.e. various probing resolutions). • High Q2 : unexplored domain • Variable Q2 • High precision measurements E89-044 experiment: December 1999! April 2000

  4. L/T separation in the 3He(e,e’p) reactionat parallel kinematics • Motivations • Quasi-elastic scattering • 3He(e,e’p) cross section • L/T separation • Experimental setup • Cross section extraction • Experimental data • Normalization • Monte Carlo simulation • Results • L/T separation • Status report • Conclusion and prospects

  5. Missing momentum : undetected momentum Missing energy : separation energy Quasi-elastic: Parallel: pm≈ 0 Quasi-elastic scattering: 3He(e,e’p)B • Only e’ and p are detected • Residual system B: Leptonic plane • Kinematical regime Hadronic plane

  6. Quasi-elastic scattering 2 body break-up peak 2-bbu 3 body break-up threshold 3-bbu

  7. : Kinematic electron coupling coefficients : Nuclear response functions σM: Mott cross section R: Recoil factor 3He(e,e’p)d cross section

  8. KIN01≠ KIN03 change photon polarization 2 points in space L/T separation: • Separation of longitudinal/transverse response functions • Interference terms ! 0 if pq! 0 (parallel kinematics) • Averaging over out-of-plane angle: ! 0 • Separation using Rosenbluth method: • Extraction of the 3He(e,e’p)d cross section at different kinematic settings • Keep same hadronic vertex and change leptonic vertex.

  9. L/T separation in the 3He(e,e’p) reactionat parallel kinematics • Motivations • Quasi-elastic scattering • 3He(e,e’p) cross section • L/T separation • Experimental setup • Cross section extraction • Experimental data • Normalization • Monte Carlo simulation • Results • L/T separation • Status report • Conclusion and prospects

  10. Experimental setup • Jefferson Laboratory (CEBAF, Newport News, USA), continuous electron beam : • Beam Energy up to 6 GeV • Beam Intensity up to 200 A • Recirculation arcs • 0.6 GeV LINAC • 67 MeV injector • 3 experimental areas • Extraction elements

  11. Experimental setup

  12. Experimental setup d, np

  13. Experimental setup 0 TOF p Electron Arm Hadron Arm

  14. L/T separation in the 3He(e,e’p) reactionat parallel kinematics • Motivations • Quasi-elastic scattering • 3He(e,e’p) cross section • L/T separation • Experimental setup • Cross section extraction • Experimental data • Normalization • Monte Carlo simulation • Results • L/T separation • Status report • Conclusion and prospects

  15. Raw Data Filter Coincidence events Background rejection Real coincidence events Accidental coincidence rejection Experimental Yield In pm and Em bins 1 Experimental data

  16. Experimental Data: Background rejection Some examples... 1 Hadron and Electron Arm Electron Arm • Events that are not reconstructed at • the same point by each spectrometer • Pion contamination Demand |zlabh-zlabe| < 0.02. Demand hit in Čerenkov counter.

  17. Experimental Data: Accidental coincidences 1 Bin experimental data in pm Per pm bin: bin in Em First bin in Em = 2-bbu bin Substract flat background: Bin in Em Accidental coincidences Experimental yield per pm, Em bin

  18. Raw Data All events Efficiency study Detector Efficiencies total deadtime target density Normalization factor 2 Luminosity

  19. Luminosity: Scintillator efficiency study 2 Scintillator efficiency study Start losing ‘good events’! Kin 03: S1-study in Hadron arm

  20. Luminosity: target density monitoring 2 Target density monitoring: Single rates Increase in target density Kin 03: Single rates vs. Run number

  21. 3 Monte Carlo simulation Experimental conditions Resolutions, Offsets, Target density Input Monte Carlo Raw simulated events Acceptance cuts Simulated Yield In pm and Em bins

  22. Monte Carlo simulation: matrix-method 3 Em Vertex Radiation effects Resolution effects Em Asymptotic Weights associated to each vertex bin Binning in EmV Binning In EmA

  23. Monte Carlo simulation: example 3 Em Vertex Radiation effects Resolution effects Em Asymptotic Resolution effect to 1st asymptotic bin Event drawn in 2nd bin Vertex Contribution to N12 Binning in EmV Binning In EmA

  24. Radiation to 3rd asymptotic bin Event drawn in 2-bbu bin Vertex (1) Contribution to N31 Monte Carlo simulation: example 3 Em Vertex Radiation effects Resolution effects Em Asymptotic Resolution effect to 1st asymptotic bin Event drawn in 2nd bin Vertex Contribution to N12 Binning in EmV Binning In EmA

  25. Cross section results Previous Analysis Current Analysis Kin 01 Kin 03

  26. Bq pq Cross section results Why this difference? Current analysis: no angle selection Bq > 90° Bq < 90° Previous Analysis Current Analysis Kin 01

  27. Cross section results Bq pq Pm>0(<0)!Bq<45°(>135°) Bq pq Previous Analysis Current Analysis pq<2°

  28. L/T separation in the 3He(e,e’p) reactionat parallel kinematics • Motivations • Quasi-elastic scattering • 3He(e,e’p) cross section • L/T separation • Experimental setup • Cross section extraction • Experimental data • Normalization • Monte Carlo simulation • Results • L/T separation • Status report • Conclusion and prospects

  29. L/T Separation: status report q vs ω for Kin01 and Kin03 • Kin01, Kin03: keep same hadronic vertex • ω/q and pm/q phase spaces need to be matched • Mean values have to be checked to be equal for Kin01 and Kin03 • Extract 2-bbu cross sections for the two kinematics at the average kinematic point.

  30. L/T Separation: status report σ

  31. L/T separation in the 3He(e,e’p) reactionat parallel kinematics • Motivations • Quasi-elastic scattering • 3He(e,e’p) cross section • L/T separation • Experimental setup • Cross section extraction • Experimental data • Normalization • Monte Carlo simulation • Results • L/T separation • Status report • Conclusion and prospects

  32. Good understanding of efficiencies • Optimization of good-event-selection • Matrix method • Gain in statistics • Iteration of matrix method • Results consistent with previous analysis • Understanding of the different aspects • concerning the separation • First results seem reasonable Conclusion and prospects • Detector in-beam efficiency study • 3He(e,e’p)d Cross section extraction • Preliminary L/T separation • Next steps? • Generalization of the matrix-method to deconvolute radiative effects between pm bins • Additional binning in Q2 • Cross section extractions and L/T separations for the remaining Q2 at parallel kinematics

More Related