Exclusive Vector Meson Electroproduction at 12 GeV Paul Stoler Rensselaer Polytechnic Institute.

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Presentation transcript:

Exclusive Vector Meson Electroproduction at 12 GeV Paul Stoler Rensselaer Polytechnic Institute

What do we want to do at 12 GeV? (a)Approach to the small–size regime (b)Learn about short–range nucleon and meson structure Is 12 GeV the right energy?

high x B valence quarks low x B sea quarks From valence quarks to sea quarks and gluons From gluon dressed to bare quarks. (Craig Roberts et al.)

GPD’s

VGG GK VGG+D JML Example of world data

GPD: n=3  Example of CLAS 6 GeV date 

Q 2 =1-3 GeV 2, W=2-3 Jlab 6 GeV Jlab 12 GeV  - d  /dt’

u =(p i − p  ) 2 small t = (p i − p p ) 2 large J.P Landsberg, B. Pire, L. Szymanowski Elastic scattering from proton core in a dressed nucleon. Backward angle (high - t ) electroproduction

Kinematic covered. W ~ 2 ➞ 4.5 GeV Q 2 ~ 1 ➞ 13 GeV 2 −t’ ~ 0 to > 15 GeV 2 Explore the transition from soft physics to the dominance of QCD quarks and gluons CLAS12 Proposal Exclusive Vector Meson Electroproduction with CLAS12

Meson Decay Modes

Goals of the experiment Goal-obtain information about all 5 structure functions available with polarized beam and unpolarized target obtained from cos(  ) and cos(2  ) with h = 0 –angular distribution of meson decay products. Beam spin cross section differences beam spin asymmetries Structure Functions:

L/T separation H H Helicity Frame

Simulations Extensive simulations were carried out for all 4 mesons channels. In general, statistics are quite good due to large acceptance, high luminosity and efficient PID Compared with previously successful CLAS 6 GeV      and  experiments, statistics will increase by factor ~10 2

 0 channel simulations

0.1 xBxB Q2Q2 1 GeV 2 13 GeV 2 0.8

0 d  /dt (  b/GeV 2 ) -t (GeV 2 ) 10 20

  simulations

Acceptance - e p K +

6 backup slides follow

Statistics Average acceptance ≃ 10 to 50%. (depending on kinematics) Systematics Background subtraction~ few % ( sharp state ) Acceptance ~5-10 % Net:  ~7-12% Errors on cross sections Statistics ⇒ Statistics: very high Average acceptance ≃ 10 to 30%. (depending on kinematics) Systematics Background subtraction: systematics 10% Net:  ~15%