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LEADING BARYON PRODUCTION at HERA Lorenzo Rinaldi On behalf of H1 and ZEUS Collaborations

LEADING BARYON PRODUCTION at HERA Lorenzo Rinaldi On behalf of H1 and ZEUS Collaborations. Motivations. Large fraction of events with a Leading Baryon (LB) LB produced at small angle in forward direction: difficult detection

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LEADING BARYON PRODUCTION at HERA Lorenzo Rinaldi On behalf of H1 and ZEUS Collaborations

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  1. LEADING BARYON PRODUCTION at HERA Lorenzo Rinaldi On behalf of H1 and ZEUS Collaborations

  2. Motivations • Large fraction of events with a Leading Baryon (LB) • LB produced at small angle in forward direction: difficult detection • Production mechanism still not clear: soft scale, alternative approach needed • Interest in LB study for next experiments @ LHC  absorptive corrections related to gap survival probability (diffractive Higgs, pile-up background...) Results discussed in this talk: • Leading Proton (LP) spectra in DIS  NEW • Leading Neutron (LN) spectra in DIS and gp • Dijet gp with a LN  NEW • Latest developments in theory • Comparison with models

  3. Leading baryon production in ep collisions p,IR,IP p p, n LB cross sections vs structure functions: (QCD-based approach) Lepton variables Q2, W, x, y Standard fragmentation • LB from hadronization of p remnant • Implemented in MC models (Cluster, Lund strings...) LB variables: pT2, xL=ELB/Ep t=(p-p’)2 Virtual particle exchange p, IR, IP, r,.. LB also from p fragmentation in double dissociative diffraction

  4. Leading baryon detectors ZEUS Leading Proton Spectrometer (LPS) • 6 stations each made by 6 Silicon-detector planes • Stations inserted at 10sbeam from the proton beam during data taking • sxL < 1% spT2~ few MeV2 (better than p-beam spread ~ 50 - 100 MeV) H1 Forward proton spectrometer (FPS) • 2 stations each made by 4 scintillating fibres hodoscopes planes • qx=5mrad qy=100mrad, Energy resolution 8 GeV • Acceptance 500<Ep’<780 GeV ZEUS Forward Neutron Calorimeter (FNC) • 10l lead-scintillator sandwich • σ/E =0.65/√E, Energy scale=2% • Acceptance qn<0.8 mrad, azimuthal coverage 30% • ZEUS Forward Neutron Tracker (FNT) • Scint. hodoscope @ 1λint, σx,y=0.23cm, σθ=22μrad H1 Forward Neutron Calorimeter (FNC) • Lead-scintillator calorimeter @ 107m from I.P. + veto hodoscopes • s(E)/E≈20%, neutron detection eff. 93±5%

  5. Leading Proton: cross section vs xL NEW NEW Flat below diffractive peak Cross section at low pT2 Agreement with photoproduction NEW LP results: LPS stations full set used

  6. LP: cross section vs pT2 and b-slopes NEW NEW No strong dependence of b on xL Exponential behaviour Fit to A*exp(-b*pT2) shown with stat. error

  7. LP: ratio to inclusive DIS Structure function ratio Information on LP production as a function of DIS variables Test of vertex factorization NEW

  8. Ratios to inclusive DIS - 2 NEW NEW No strong dependence on x and Q2 when integrating over 0.5<xL<0.92 No clear evidence of vertex factorization violation 17-18% of DIS events have a LP with 0.5<xL<0.92, almost independently of x and Q2

  9. LP structure functions NEW NEW F2LP=rLP*F2 (ZEUS-S parametrization used) F2LP: same dependence on x and Q2 as F2

  10. Comparisons to Reggeon exchange model Predictions good in shape but: xL slighty underestimated b-slope slightly overestimated Szczurek et al., Phys Lett B428, 383 (1998) Pomeron Reggeon pD pN

  11. Leading Neutron: One-Pion-Exchange model O.P.E. partially explains the LN production a(t) and form factor F2(xL,t) model dependent Longitudinal momentum spectrum and pT2 slopes discriminate between different parametrizations of fluxes

  12. Rescattering model and absorption DIS gp • D’Alesio and Pirner • (EPJ A7(2000) 109) • Neutron rescatters on g hadronic component. • Absorption enhanced when • p-n system size larger  low xL • g size larger  photoproduction Nikolaev,Speth and Zakharov (hep-ph/9708290) Re-scattering processes via additional Pomeron exchanges (Optical Theorem) Kaidalov, Khoze, Martin, Ryskin (KKMR) (hep-ph/0602215, hep-ph/0606213) Enhanced absorptive corrections ( exclusive Higgs @ LHC), calculation of migrations, include also rand a2 exchange (different xL & pT dependences)

  13. LN: longitudinal momentum spectrum Phase space coverage • LN yield increases with xL due to increase in phase space: pT2 < 0.476 xL2 • LN yield decreases for xL1 due to kinematic limit DIS

  14. LN: ratio gp/DIS • Data compared to OPE with absorption. • Qualitatively similar to D’Alesio and Pirner (loss through absorption) • Nikolaev,Speth and Zakharov model also shown: similar trend but weaker xL dependence gp DIS W dependence: s~Wa, a(sgp) a(sg*p) Wp2=(1-xL)Wp2 (1-xL) -0.13 absorption rate rescaled • Models in agreement with data • LN yield in PHP < yield in DIS •  factorization violation

  15. LN: KKMR absorption model gp • Kaidalov, Khoze, Martin, Ryskin: • Pure p exchange (not shown) too high • Absorption and migration effects reduce the LN yield and fit the data better • Additional r and a2 exchanges enhance the LN yield

  16. LN: DIS cross section vs pT2 in xL bins • pT2 distributions well described by an exponential • Intercept a(xL) and slopes b(xL) fully characterize the xL-pT2 spectra

  17. LN: intercepts and slopes in DIS b consistent with 0 for xL<0.3

  18. LN b-slopes: DIS & photoproduction comparison DIS slopes different in gp and DIS in general agreement with expectation from absorption models gp Fit to exponential

  19. LN b-slopes: comparison to models OPE models: • Dominant at 0.6<xL<0.9 • (non-) Reggeized flux, different form factors with different parameters • none of the models seem to decribe the data well KKMR model: good description of the data considering absorption effects and r,a2 exchange contributions

  20. LN spectrum: Q2 dependence 3 Q2 bins + gp • LN yield increases monotonically with Q2 • consistent with absorption (larger Q2 smaller g)

  21. Comparisons LP - LN data Very similar behaviour xL<0.85 LP cross section almost twice LN In particle exchange model: expected from isospin-1: LP=1/2LN Other exchanges needed (isoscalars) Slopes comparable 0.7<xL<0.8 where p exchange dominates

  22. LN production compared to MC predictions • Compare LN DIS distribution to MC models: • RAPGAP standard fragmentation • RAPGAP OPE • LEPTO standard fragmentation • LEPTO soft color interaction • Both standard fragmentation fail • Too few n, too few xL • b-slopes too low • RAPGAP-OPE: close to data in shape but not in magnitude • LEPTO-SCI: reasonable description of xL spectrum and intercepts, bad slopes • Other models also fail (ARIADNE, CASCADE,PYTHIA,PHOJET)

  23. Dijet gp with a LN Presence of jets hard-scale Naively, rescattering effects expected in resolved photoproduction:  low xg, photon acts like a hadron H1 data: ratios (jj+LN)/jj reasonably well described by photoproduction MC

  24. Dijet with a LN NEW Ratios (LN+jj)/jj Model by Klasen and Kramer based on OPE Ratios well described by NLO predictions NEW xL spectrum: Reasonable shape, NLO too high

  25. Dijet production with a LN NEW epejjnX vs epenX Suppression observed in dijet+LN: Kinematic or absorption/rescattering? Look at xBP=1-(E+pZ)/2Ep Fraction of proton beam energy available for particle production in the forward beampipe Kinematic constraint: xL<xBP The lower xBP values in dijet-gp constrain the neutrons to lower xL than DIS NEW

  26. Dijet with a LN NEW After reweighting xBP, the xL distributions of the two processes epejjnX and epenX agree: Mainly kinematic effect, no clear evidences of absorption b-slopes No significant difference within errors NEW

  27. Summary • LP spectra in DIS; well described by Reggeon-exchange model • LP production as a function of DIS variables: no dependence observed • LN production measured in DIS and gp • LN characterized by rescattering and absorption effects: well reproduced by some models • MC generators in general fail to reproduce the measured quantities  need to tune the generators • Dijet-gp with LN: suppression most probably due to kinematic effects. HERA provided high precision measurements of leading baryon production. Now it’s time to work together with theory people and apply our knowledge to the next future physics

  28. Rescattering model and absorption 1 Model 1: One pion exchange in the framework of triple-Regge formalism Nikolaev,Speth & Zakharov Re-scattering processes via additional pomeron exchanges (Optical Theorem) (hep-ph/9708290) (Kaidalov,) Khoze, Martin, Ryskin (KKMR) Enhanced absorptive corrections ( exclusive Higgs @ LHC), calculation of migrations, include also rand a2 exchange (different xL & pT dependences) (hep-ph/0602215, hep-ph/0606213)

  29. Rescattering model and absorption 2 Model 2: calculations from D’Alesio and Pirner in the framework of target fragmentation (EPJ A7(2000) 109) DIS • more absorption when photon size larger (small Q2)  less neutrons detected in photoproduction • more absorption when mean p-n system size (‹rnp›) smaller at low xL  less neutrons detected at low xL • more absorption  fewer neutrons detected with higher pT2  larger b-slope expected in photoproduction gp

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