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A High Precision Measurement of the Deuteron Spin-Structure Function Ratio g 1 /F 1  Motivation  Proposed Experiment  Expeced Results Co:spokespersons:

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Presentation on theme: "A High Precision Measurement of the Deuteron Spin-Structure Function Ratio g 1 /F 1  Motivation  Proposed Experiment  Expeced Results Co:spokespersons:"— Presentation transcript:

1 A High Precision Measurement of the Deuteron Spin-Structure Function Ratio g 1 /F 1  Motivation  Proposed Experiment  Expeced Results Co:spokespersons: P. Bosted. F. Wesselmann, X. Jiang PAC 31, January 2007  G(x)

2 2 Spin Structure of the Nucleon  Spin sum rule: total spin 1/2 formed by quarks (small), gluons, and orbital angular momentum (sum of these must be big).  How much carried by gluons?: major focus of large experimental program worldwide (RHIC, DESY, CERN, JLab…).  One of DOE milestone for JLab is precision measurement of spin structure to Q 2 =4 GeV 2

3 3 Polarized DIS  Theoretically cleanest was to learn about polarized gluons is through pQCD evolution in deep inelastic scattering (DIS)  Q 2 -dependence at fixed x influenced by gluon radiation [log(Q 2 )]. Wilson coefficients calculated to NLO in pQCD.  Largest sensitivity at low Q 2 where  s largest (but need to account for power law higher twist)

4 4 Valence Quarks  Pretty well known now, primarily from measurements of proton and neutron g 1

5 5 Gluons and Sea Quarks Gluon polarization poorly known (just that not maximal, probably positive). Need more precise data! Main goal of this experiment. Sea quark knowledge will improve with SIDIS studies in future.

6 6  Why deuteron best for  G(x)? The  q 3 terms from p and n, about twice size of  q 8 and  erms, cancels in deuteron. Relative gluon contributions largest in deuteron: relevant as experimental errors dominated by syst. scale factors. q3q3 q8q8 

7 7 Complementary to RHIC-SPIN Measurements such as  0 from STAR (left) and PHENIX (right) as a function of p t probe x<0.1. This proposal sensitive to x>0.1. Results so far rule out  G=G.

8 8 SLAC, DESY, CERN g 1 /F 1 data x>0.1

9 9 Add recent DIS data CLAS Hall B

10 10 Physics Impact Adding the CLAS data to the analysis of the LSS group (NLO plus Higher Twist) had a major impact on error band of  G(x) Without CLAS With CLAS With 12 GeV

11 11 Proposed Kinematic Coverage “6” GeV (>5.7) 4.8 GeV BETA HMS

12 12 Proposed data shown in red (systematic errors included)

13 13 Significant improvement in  G(x) and neutron HT Physics Impact in LSS framework without With this proposal Error on  G(x) HT coefficients

14 14 Relative error on  G [first moment  G(x)] Physics Impact in AAC framework 1) World DIS without CLAS Eg1b: 2.08 2) World DIS with CLAS Eg1b: 1.48 3) With this Proposal: 0.96 4) With existing  0 data RHIC: 0.91 Significant improvement in  G

15 15 6 Li as Polarized Deuteron Most high Q 2 experiments used (SLAC) or are using (COMPASS) 6 LiD as target (blue points on next slide). 6 Li treated as unpolarized alpha particle plus deuteron with polarization 87% that of the free proton. If this wrong, will bias Q 2 dependence of g 1 and hence extracted gluon polarization. Global problem we can solve.

16 16 Existing 6 LiD data in Blue

17 17 Nuclear effects in 6 Li Ratio of g 1 6 Li to D (using ND 3 ) Polarized “EMC effect” model of Cloet, Bentz and Thomas (for 7 Li) relative to nominal nuclear model Proposal errors assuming nominal model

18 18 Experimental Setup Longitudinally polarized beam 4-pass and 5-pass (>5.7 GeV), 100 nA Uva/Jlab/SLAC Polarized target setup with longitudinally polarized ND 3 and 6 LiD Inclusive electrons detected in BETA centered at 30 degrees (and HMS) Identical to D part of approved Semi-SANE experiment except for trigger (single-arm instead of coincidence) and using ND 3 for half of time (original experiment all 6 LiD).

19 19 Front Tracker Experimental Setup

20 20 Systematic Errors (N/A for ND 3 )

21 21 Quasi-elastic Measurement At low Q 2, deuteron quasi-elastic peak clearly visible in HMS spectrometer (see next slide). Use absolute cross sections to measure D content of the ND 3 target. Cross check of ratio of ND 3 to C rates in BETA and HMS. Use double-spin asymmetry to obtain product of beam and target polarization (compare with full calculation of Arenhoevel including MEC and FSI). Cross check with beam Moller and target NMR (two methods).

22 22 Quasi-elastic Measurement Sum N+He+Al Curves from Fit to Jlab data (P. Bosted et al.) D

23 23 Request 19 days production (12 shared with Semi- SANE, 7 new) 5 days overhead (4 shared, 1 new) Only 8 new PAC days needed DAQ upgrade to 5 kHz (planned in any case)

24 24 Readiness > SANE expected to be ready by early 2008 >DAQ upgrade can be done by early 2008 also. > This proposal could run immediately after SANE, with only a few shifts needed to change BETA angle from 40 to 30 degrees. Save on major installation time as well as need to re-calibrate BigCal.

25 25 Collaboration 79 collaborators from 22 institutions. Strong overlap with SANE, Semi-SANE, polarized Compton experiments Expertise in BigCal, BETA, HMS, polarized target, polarimetry, data analysis. Two young enthusiastic spokespersons (one did thesis on g 1d ) that can carry polarized target physics into 12 GeV era.

26 26 Thanks D. Stamenov and A. Sidorov of LSS group (motivation slides and physics impact study) M.Hirai, S. Kumano, and N. Saito of AAC group for detailed physics impact study.

27 27 Why Now? For 1<Q 2 <10x, 11 GeV has no advantage over 6 GeV: already systematic error limited in 8 PAC days. Combining with approved CLAS experiment at 11 GeV (1<Q 2 <20x) will Improve  G(x), because both experiments orthogonally systematic error limited (different target, beam line) This is compelling physics with wide interest worldwide: a bird in the hand…

28 28 Definitive measurements of deuteron g 1 /F 1 in DIS range accessible at Jlab. Significant improvement in knowledge of fundamental polarized gluon distribution Improved measurements of Higher Twist Test of 6 Li as polarized deuteron: needed for interpretation of high Q 2 data. Relatively inexpensive and low overhead (assuming done just after SANE and jointly with Semi-SANE). High impact physics: lets do it soon! Summary

29 29 Backup Slides

30 30 Why not Hall B? > Main reason: would take approximately factor of 5 to 10 more beam time for same statistical errors (60x lower luminosity, 3x larger solid angle, 1.4x higher polarization), assuming current limited to 5 nA to 10 nA by drift chamber occupancy. > Upgrade to target stick would be needed to embed NMR coils in target cell. > BUT, would allow additional physics topics (i.e. polarized DVCS on deuteron).

31 31 Proton plus neutron as “deuteron” Alternative to deuteron target to obtain isoscaler combination is to add free proton plus neutron extracted from 3 He Due to scale factor systematic errors, resulting errors larger than for an actual deuteron target. Projected errors from SANE plus Hall A d 2 experiment shown on next slide (blue). Existing Hall B plus A data also shown. On other hand, allows test of 3 He as polarized neutron target

32 32 Proton plus neutron as “deuteron”

33 33 Pion, e+, radiative corrections

34 34 Correction from g 2 Will be sufficiently well known from SANE (p) and Hall A (n)

35 35 Statistical and Systematic Errors Well matched for study of Q 2 dependence

36 36 Physics Impact in LSS framework Impact on polarized quark distributions relatively small

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