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PAX project at FAIR http://www.fz-juelich.de/ikp/pax Marco Contalbrigo – INFN and Università di Ferrara - ITALY Tbilisi, 5 September 2006 M. Contalbrigo.

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Presentation on theme: "PAX project at FAIR http://www.fz-juelich.de/ikp/pax Marco Contalbrigo – INFN and Università di Ferrara - ITALY Tbilisi, 5 September 2006 M. Contalbrigo."— Presentation transcript:

1 PAX project at FAIR Marco Contalbrigo – INFN and Università di Ferrara - ITALY Tbilisi, 5 September 2006 M. Contalbrigo PAX Polarized Antiproton Experiments

2 PAX Polarized Antiproton Experiments
Physics Program M. Contalbrigo PAX Polarized Antiproton Experiments

3 Polarized Antiproton eXperiments
Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target Nucleon structure: polarized reactions Cerenkov pbar-p elastic M. Contalbrigo PAX Polarized Antiproton Experiments

4 PAX Polarized Antiproton Experiments
Elastic Scattering Low-E pp, pd at AD Polarization build-up studies T=10.85 GeV High-t pp from ZGS, AGS Spin-dependence at large-P (90°cm): Hard scattering takes place only with spins . t=-2Pcm2(1-cos(cm)) Similar studies in pp elastic scattering D.G. Crabb et al., PRL 41, 1257 (1978) M. Contalbrigo PAX Polarized Antiproton Experiments

5 Polarized Antiproton eXperiments
Nucleon structure: polarized reactions Cerenkov pbar-p elastic Proton EFFs Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target M. Contalbrigo PAX Polarized Antiproton Experiments

6 Proton Electromagnetic Formfactors
COMPARISON BETWEEN ROSENBLUTH SEPARATION AND POLARIZATION TRANSFER TECNIQUES JLab PT data SLAC RS data TWO DIFFERENTS METHODS TWO DIFFERENTS RESULTS (Phys. Rev.C 68 (2003) ) M. Contalbrigo PAX Polarized Antiproton Experiments

7 Proton Electromagnetic Formfactors
Double-spin asymmetry in pp → e+e- independent GE-Gm separation test of Rosenbluth separation in the time-like region Single-spin asymmetry in pp → e+e- Measurement of relative phases of magnetic and electric FF in the time-like region S. Brodsky et al., Phys. Rev. D69 (2004) M. Contalbrigo PAX Polarized Antiproton Experiments

8 Polarized Antiproton eXperiments
Nucleon structure: polarized reactions Asymmetric collider (√s=15 GeV): polarized antiprotons in HESR (p=15 GeV/c) polarized protons in CSR (p=3.5 GeV/c) Parton distribution: transversity Cerenkov Drell-Yan pbar-p elastic Proton EFFs Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target M. Contalbrigo PAX Polarized Antiproton Experiments

9 Leading Twist Distribution Functions
proton proton’ quark quark’ Probabilistic interpretation in helicity base: 1/2 R 1/2 L f1(x) + q(x) spin averaged (well known) 1/2 R 1/2 L g1(x) - Dq(x) helicity diff. (known) No probabilistic interpretation in the helicity base (off diagonal) 1/2 -1/2 R L h1(x) Transversity base u = 1/2(uR + uL) u = 1/2(uR - uL) - dq(x) helicity flip (unknown) M. Contalbrigo PAX Polarized Antiproton Experiments

10 Transversity Chiral-odd: requires another chiral-odd partner
Properties: Probes relativistic nature of quarks No gluon analog for spin-1/2 nucleon Different Q2 evolution than Dq Sensitive to valence quark polarization See talk by M. Anselmino Chiral-odd: requires another chiral-odd partner epe’X epe’hX ppe+e-X Impossible in DIS Direct Measurement Indirect Measurement: convolution with unknown fragment. fct. h1 must couple to another chiral-odd function h1 x h1 h1 x Collins function M. Contalbrigo PAX Polarized Antiproton Experiments

11 Drell-Yan process Plenty of single and double spin effects
Elementary LO interaction: M invariant Mass of lepton pair M. Contalbrigo PAX Polarized Antiproton Experiments Plenty of single and double spin effects

12 h1q (x, Q2) small and with much Δq(x, Q2) and q(x, Q2) at small x
h1 from p-p Drell-Yan 1 2 h1q (x ,Q2) h1q (x, Q2) small and with much slower evolution than Δq(x, Q2) and q(x, Q2) at small x - h1q (x, Q2) Barone, Calarco, Drago Martin, Schäfer, Stratmann, Vogelsang RHIC: M2/s=x1x2~ → sea quarks (ATT ~ 0.01 ) JPARC/U70: M2/s=x1x2~ → valence and sea (ATT ~ 0.1 ) PAX: M2/s=x1x2~ → valence and sea (ATT ~ 0.1 ) M. Contalbrigo PAX Polarized Antiproton Experiments

13 h1 from pbar-p Drell-Yan
M2 > 4 GeV2 Anselmino et al. PLB 594,97 (2004) Similar predictions by Efremov et al., Eur. Phys. J. C35, 207 (2004) PAX : M2/s=x1x2~ → valence quarks (ATT large ~ ) M. Contalbrigo PAX Polarized Antiproton Experiments

14 DY events distribution
p-pbar p-p M2/s = x1x2 ~ At x1=x2 ATT ~ h1u2 Extraction of h1u for x<0.2 Direct measurement of h1u for 0.05<x<0.5 pbarp+pp complete mapping of transversity M. Contalbrigo PAX Polarized Antiproton Experiments

15 Polarized Antiproton eXperiments
Nucleon structure: polarized reactions Asymmetric collider (√s=15 GeV): polarized antiprotons in HESR (p=15 GeV/c) polarized protons in CSR (p=3.5 GeV/c) Parton distribution: transversity Cerenkov Drell-Yan pbar-p elastic SSA Proton EFFs Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target M. Contalbrigo PAX Polarized Antiproton Experiments

16 Single Spin Asymmetries (and their partonic origin)
π Pq k┴ Collins effect = fragmentation of polarized quark depends on Pq· (pq x k┴) pq q P k┴ Sivers effect = number of partons in polarized proton depends on P · (p x k┴) p Pq q Boer-Mulders effect = polarization of partons in unpolarized proton depends on Pq · (p x k┴) k┴ p Collins: chiral-odd Sivers: chiral-even Boer-Mulders: chiral-odd These effects may generate SSA See talk by O. Ivanov, M. Anselmino, O.Shevchenko M. Contalbrigo PAX Polarized Antiproton Experiments

17 SSA, pp → πX BNL-AGS √s = 6.6 GeV 0.6 < pT < 1.2 p↑p
E704 √s = 20 GeV < pT < p↑p STAR-RHIC √s = 200 GeV 1.1 < pT < p↑p E704 √s = 20 GeV 0.7 < pT < p↑p SSA, pp → πX M. Contalbrigo PAX Polarized Antiproton Experiments

18 PAX Polarized Antiproton Experiments
Collins HERMES Sivers See talk by L. Pappalardo SSA, SIDIS M. Contalbrigo PAX Polarized Antiproton Experiments

19 Polarized Antiproton eXperiments
Nucleon structure: polarized reactions Asymmetric collider (√s=15 GeV): polarized antiprotons in HESR (p=15 GeV/c) polarized protons in CSR (p=3.5 GeV/c) Parton distribution: transversity Cerenkov Drell-Yan pbar-p elastic SSA Proton EFFs Charmonium Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target M. Contalbrigo PAX Polarized Antiproton Experiments

20 PAX Polarized Antiproton Experiments
Kinematics for Drell-Yan processes Fermilab E GeV/c CERN NA GeV/c Q2>4 GeV2 "safe region" Usually taken as QCD corrections might be very large at smaller values of M, for cross-sections, not for ATT: K-factor almost spin-independent H. Shimizu, G. Sterman, W. Vogelsang and H. Yokoya, hep-ph/ V. Barone et al., in preparation M. Contalbrigo PAX Polarized Antiproton Experiments

21 measure ATT also in J/ψ resonance region
q l+ q l+ J/ψ q l– q l– all vector couplings, same spinor structure and, at large x1, x2 measure ATT also in J/ψ resonance region M. A., V. Barone, A. Drago and N. Nikolaev M. Contalbrigo PAX Polarized Antiproton Experiments

22 PAX Polarized Antiproton Experiments
The FAIR project M. Contalbrigo PAX Polarized Antiproton Experiments

23 Facilty for Antiproton and Ion Research (GSI, Darmstadt, Germany)
Proton linac (injector) 2 synchrotons (30 GeV p) A number of storage rings  Parallel beams operation M. Contalbrigo PAX Polarized Antiproton Experiments

24 PAX Polarized Antiproton Experiments
PAX Accelerator Setup APR: Antiproton Polarizer Ring (Ppbar>0.2) CSR: Cooled Synchrotron Ring ( p<3.5 GeV/c) HESR: High Energy Synchrotron Ring (p<15 GeV/c) M. Contalbrigo PAX Polarized Antiproton Experiments

25 PAX Polarized Antiproton Experiments
PAX Detector Concept GEANT simulation (200 mm) (20 mm) Designed for Collider but compatible with fixed target M. Contalbrigo PAX Polarized Antiproton Experiments

26 Polarized Antiproton eXperiments
Phase I: Proton time-like FFs Hard pbar-p elastic scatt. Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target From few hours to few weeks measurements M. Contalbrigo PAX Polarized Antiproton Experiments

27 Polarized Antiproton eXperiments
1 year of run Phase II: Transversity Distribution Asymmetric collider (√s=15 GeV): polarized antiprotons in HESR (p=15 GeV/c) polarized protons in CSR (p=3.5 GeV/c) 10 % precision on the h1u(x) in the valence region M. Contalbrigo PAX Polarized Antiproton Experiments

28 RINGS SETUP Asymmetric collider Luminosity up to 1031 cm-2s-1
See talk by Y. Shatunov, D. Prasuhn, A. Garishvili, A. Smirnov M. Contalbrigo PAX Polarized Antiproton Experiments

29 Antiproton Polarization
M. Contalbrigo PAX Polarized Antiproton Experiments

30 1992 Filter Test at TSR with protons Experimental Proof of Principle
Results Experimental Setup T=23 MeV F. Rathmann. et al., PRL 71, 1379 (1993) Experimental Proof of Principle M. Contalbrigo PAX Polarized Antiproton Experiments

31 Spin-filtering: Present situation
Spin filtering works, but: controversial interpretations of TSR result no experimental basis for antiprotons Experimental tests: - Protons (COSY at FZJ) - Antiprotons (AD at CERN) See talk by P. Lenisa M. Contalbrigo PAX Polarized Antiproton Experiments

32 Hadronic Interaction in p-pbar: Longitudinal Case Beam Polarization
Model D: V. Mull, K. Holinde, Phys. Rev. C 51, 2360 (1995) Model A: T. Hippchen et al., Phys. Rev. C 44, 1323 (1991) 50 100 150 200 250 T (MeV) 0.05 0.10 0.15 0.20 P 3 beam lifetimes Ψacc=20 mrad 2 beam lifetimes Ψacc=10-50 mrad Filter Test: T = 23 MeV Ψacc= 4.4 mrad M. Contalbrigo PAX Polarized Antiproton Experiments

33 PAX Polarized Antiproton Experiments
Summary PAX project has an innovative spin physics program * transversity * SSA * EMFF * hard p-pbar scatterings * polarized charmonium production A method to obtain an antiproton beam with high degree of polarization has to be optimized (APR) PAX viable accelerator setup at FAIR provides fexible 2nd IP really matched to the physics items * lots of interesting QCD physics in PAX Phase-I * asymmetric collider ideal to map transversity (Phase-II) M. Contalbrigo PAX Polarized Antiproton Experiments

34 Timeline Fall 2006 Technical Proposal for COSY-ANKE
Propedeutical studies at COSY-ANKE Technical Proposal for COSY-New IP Technical Proposal for AD Design and construction phase COSY Spin-filtering studies at COSY Commissioning of AD experiment Installation at AD Spin-filtering studies at AD M. Contalbrigo PAX Polarized Antiproton Experiments

35 Drell-Yan process Plenty of single and double spin effects
Elementary LO interaction: M invariant Mass of lepton pair M. Contalbrigo PAX Polarized Antiproton Experiments Plenty of single and double spin effects

36 PAX Polarized Antiproton Experiments
Kinematics for Drell-Yan processes Fermilab E GeV/c CERN NA GeV/c Q2>4 GeV2 "safe region" Usually taken as QCD corrections might be very large at smaller values of M, for cross-sections, not for ATT: K-factor almost spin-independent H. Shimizu, G. Sterman, W. Vogelsang and H. Yokoya, hep-ph/ V. Barone et al., in preparation M. Contalbrigo PAX Polarized Antiproton Experiments

37 PAX Polarized Antiproton Experiments
Cross-section s=210 GeV2 s=45 GeV2 Asymmetry s=210 GeV2 s=45 GeV2 M. Contalbrigo PAX Polarized Antiproton Experiments

38 measure ATT also in J/ψ resonance region
q l+ q l+ J/ψ q l– q l– all vector couplings, same spinor structure M. A., V. Barone, A. Drago and N. Nikolaev measure ATT also in J/ψ resonance region M. Contalbrigo PAX Polarized Antiproton Experiments

39 Polarized Antiproton eXperiments
Nucleon structure: polarized reactions Asymmetric collider (√s=15 GeV): polarized antiprotons in HESR (p=15 GeV/c) polarized protons in CSR (p=3.5 GeV/c) Parton distribution: transversity Drell-Yan Charmonium Cerenkov pbar-p elastic Proton EFFs Fixed target experiment (√s<2 GeV): pol./unpol. pbar beam (p<4 GeV/c) internal H polarized target M. Contalbrigo PAX Polarized Antiproton Experiments

40 PAX Polarized Antiproton Experiments
COMPASS SSA, SIDIS M. Contalbrigo PAX Polarized Antiproton Experiments

41 PAX Polarized Antiproton Experiments
Cross-section s=210 GeV2 s=45 GeV2 Asymmetry s=210 GeV2 s=45 GeV2 M. Contalbrigo PAX Polarized Antiproton Experiments

42 Polarized antiprotons: present situation
Intense beam of polarized pbar never produced: Conventional methods (ABS) not appliable Polarized pbar from antilambda decay I< 1.5∙105 s-1 (P ≈ 0.35) Stern-Gerlach separation of a stored beam (M. Conte and M. Pusterla) Interaction with polarized electron beam (Th. Walcher et al) Spin-filtering is the only succesfully tested technique M. Contalbrigo PAX Polarized Antiproton Experiments

43 Principle of spin filter method
P beam polarization Q target polarization k || beam direction σtot = σ0 + σ·P·Q + σ||·(P·k)(Q·k) transverse case: longitudinal case: For initially equally populated spin states:  (m=+½) and  (m=-½) Unpolarized anti-p beam Polarized H target M. Contalbrigo PAX Polarized Antiproton Experiments

44 Polarized atomic beam source
|1> mj = +1/2 mj = -1/2 mi=-1/2 mi=+1/2 1 |1> |2> |3> |4> Atoms with mj=+½ focused in sextupole magnets. RF transitions select HFS. M. Contalbrigo PAX Polarized Antiproton Experiments

45 Two interpretations of FILTEX result Spin-filtering works! But how?
Observed polarization build-up: dP/dt = ± (1.24 ± 0.06) x 10-2 h-1 P(t)=tanh(t/τ1), 1/τ1=σ1Qdtf σ1 = 72.5 ± 5.8 mb Spin-filtering works! But how? 1994. Meyer and Horowitz: three distinct effects Selective removal through scattering beyond θacc=4.4 mrad (σR=83 mb) Small angle scattering off target prot. into ring acceptance (σS=52 mb) Spin-transfer from pol. el. of target atoms to stored prot. (σE=-70 mb) σ1= σR+ σS + σE = 65 mb 2005. Milstein & Strakhovenko + Nikolaev & Pavlov: only one effect Selective removal through scattering beyond θacc=4.4 mrad (σR=85.6 mb) No contribution from other two effects (cancellation between scattering and transmission) σ1 = 85.6 mb M. Contalbrigo PAX Polarized Antiproton Experiments

46 How to disentangle had. and elm contributions?
1: Injection of different combination of hyperfine states Different combinations of elm. and hadronic contributions: Pure polarization possible in strong holding field Inj. states Pe Pz Interaction Holding field |1> +1 Elm. + had. Transv. + Long. Weak (20 G) |1>+|4> Only had. Long. Strong. (3kG) |1>+|2> Only elm 2: Longitudinal and transverse target polarization 3: Beam energy variation 4: Beam acceptance variation Different behaviour of elm. and hadronic contribution M. Contalbrigo PAX Polarized Antiproton Experiments

47 Polarizing cross-section for the two models
TSR … only had - elm. + had. A measurement of s with 10 % precision is sufficient. Polarization measurement with DP/P = 10% requested. M. Contalbrigo PAX Polarized Antiproton Experiments

48 Measurements at COSY at FZJ (2008-2009)
Existing ANKE setup Only weak transverse field possible. Goals: Propedeutical studies (beam lifetime) Depolarization studies (e effect) Reproduce TSR set-up M. Contalbrigo PAX Polarized Antiproton Experiments

49 Measurements at COSY at FZJ (2008-2009)
New low-beta IP Strong and weak field polarized target Goals: Disentangle h and e effects Commissioning of AD setup M. Contalbrigo PAX Polarized Antiproton Experiments

50 Low beta section bx,ynew=0.3 -> increase a factor 30 in density respect ANKE Lower buildup time, higher rates Higher polarization buildup-rate due to higher acceptance Use of HERMES target (in Jülich since March 2006) S.C. quadrupole development applicable to AD experiment M. Contalbrigo PAX Polarized Antiproton Experiments

51 PAX Polarized Antiproton Experiments
Detector concept Reaction: p-p elastic (COSY) p-pbar elastic (AD) Good azimuthal resolution (up/down asymmetries) Low energy recoil (<8 MeV) Teflon cell Silicon tracking telescope Angular resolution on the forward particle for p-pbar M. Contalbrigo PAX Polarized Antiproton Experiments

52 The ANKE silicon tracking telescope
3 silicon detector layers 69 µm silicon 300/500 µm silicon 128 x 151 segments 51 x 66 mm (≈400 µm pitch) >5 mm Si(Li) 96 x 96 strip 64 x 64 mm (≈666 µm Pitch) cluster beam COSY beam 52 M. Contalbrigo PAX Polarized Antiproton Experiments

53 ANKE vs new interaction point
Cross sections Polarization New IP … elm + had - only had. ANKE PIT Filter. time Polar. Total rate Meas. Time (DP/P=10%) ANKE 2t = 16 h 1.2 % 7.5x102 s-1 44 min 5t = 42 h 3.5 % 5x10 s-1 26 min New IP 2t = 5 h 16 % 2.2x104 s-1 1 s 5t = 13 h 42 % 1.5x103 s-1 < 1 s T=40 MeV Ninj=1.5x1010 M. Contalbrigo PAX Polarized Antiproton Experiments

54 Measurements at AD at CERN (2009-2010)
study of spin-filtering in pp scattering Target Snake Commissioned At COSY For longitudial Polarization T:5 MeV÷2.8 GeV Np = 3·107 E-cooler Measurement of effective polarization cross-section. Both transverse and longitudinal. Variable ring acceptance.and beam energy H and D terget First measurement at all for spin correlations in pp (not pure text experiment!) M. Contalbrigo PAX Polarized Antiproton Experiments

55 Proton Electromagnetic Formfactors
Single-spin asymmetry in pp → e+e- Measurement of relative phases of magnetic and electric FF in the time-like region Double-spin asymmetry in pp → e+e- independent GE-Gm separation test of Rosenbluth separation in the time-like region S. Brodsky et al., Phys. Rev. D69 (2004) M. Contalbrigo PAX Polarized Antiproton Experiments

56 pp Elastic Scattering from ZGS
Spin-dependence at large-P (90°cm): Hard scattering takes place only with spins . T=10.85 GeV Similar studies in pp elastic scattering t=-2Pcm2(1-cos(cm)) D.G. Crabb et al., PRL 41, 1257 (1978) M. Contalbrigo PAX Polarized Antiproton Experiments

57 PAX Polarized Antiproton Experiments
q-p Phase Space acceptance Background peaks at * low energy * forward direction M. Contalbrigo PAX Polarized Antiproton Experiments

58 Background to Drell-Yan e+e-
½ hour experiment: 2∙108 p-pbar interactions several DY events +- ++ & -- combinatorial +charm bckg Background 1:1 to signal after PID, E>300 MeV, conversion veto, mass cut * the combinatorial component can be subtracted (wrong-sign control sample) * the charm can be reduced (vertex decay) M. Contalbrigo PAX Polarized Antiproton Experiments

59 PAX Polarized Antiproton Experiments
q-p Phase Space Better than 2% mass resol * x dependence of h1 * resonance vs continuum Mandatory to study M below J/ψ mass Vertex resolution high enough to study charm background M. Contalbrigo PAX Polarized Antiproton Experiments

60 Transversity Chiral-odd: requires another chiral-odd partner
Properties: Probes relativistic nature of quarks No gluon analog for spin-1/2 nucleon Different Q2 evolution than Dq Sensitive to valence quark polarization See talk by M. Anselmino Chiral-odd: requires another chiral-odd partner epe’hX ppe+e-X Impossible in DIS Direct Measurement Indirect Measurement: convolution with unknown fragment. fct. h1 must couple to another chiral-odd function h1 x h1 h1 x Collins function M. Contalbrigo PAX Polarized Antiproton Experiments

61 ≠ h1 from p-p Drell-Yan h1q (x, Q2)
h1q (x, Q2) small and with much slower evolution than Δq(x, Q2) and q(x, Q2) at small x h1q (x, Q2) - Barone, Calarco, Drago Martin, Schäfer, Stratmann, Vogelsang RHIC: M2/s=x1x2~ → sea quarks (ATT ~ 0.01 ) JPARC/U70: M2/s=x1x2~ → valence and sea (ATT ~ 0.1 ) PAX: M2/s=x1x2~ → valence and sea (ATT ~ 0.1 ) M. Contalbrigo PAX Polarized Antiproton Experiments

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