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Leading Baryon Production at HERA. HERA. Recent Measurements Developments in Theory Comparisons to Monte Carlo Simulations. Kerstin Borras ICHEP 2006 RAS Moscow (DESY). Motivation.
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Leading Baryon Production at HERA HERA • Recent Measurements • Developments in Theory • Comparisons to Monte Carlo Simulations Kerstin Borras ICHEP 2006 RAS Moscow (DESY)
Motivation • Significant fraction of ep scattering events contain a leading baryon in the final state carrying a substantial proportion of the energy of the incoming proton • Production models not yet completely understood p´,n p´,n • Standard target fragmentation: • complex final-state with p or n in proton remnant • or p stays intact Particle exchange (à la Regge): p: iso-scalar, iso-vector (IR, ρ, a2 …) n: iso-vector (π, ρ, a2 …)
xL ´,n Kinematics and Vertex Factorization Photon vertex: lepton variables Q2, x , W , y Proton vertex: leading baryon variables xL= Ep´,n/Ep t = (p – p´)2 - pT2 / xL Cross section dependence on leading baryon variables independent of kinematics at photon vertex W Violation of factorization in LB production similar as in diffraction: re-scattering processes can lead to absorption and migrations
Theory: two absorption models available 1) Calculations from D’Alesio & Pirner: (EPJ A7(2000)109) DIS: small (point-like) photon no re-scattering PHP: large (hadron-like) photon re-scattering n kickedto lower xL and higher pT (migration) might escape detection (absorption) Theoretical models (I) Production of leading neutrons or protons during the fragmentation process. check, if standard settings of the MC generators reproduce the measured xL and pT2 distributions (see plots at the end of the talk). p,n
Re-scattering processes via additional pomeron exchanges (Optical Theorem) Nikolaev,Speth & Zakharov (hep-ph/9708290) Enhanced absorptive corrections ( exclusive Higgs @ LHC), calculation of migrations, include also ρ and a2 exchange (different xL & pT dependences) (Kaidalov,) Khoze, Martin, Ryskin (KKMR) (hep-ph/0602215, hep-ph/0606213) Theoretical models (II) 2) One pion exchange in the framework of triple-Regge formalism
Leading Baryon Detection Forward Neutron Calorimeter (FNC) 10 λint Pb-Sc sandwich, σ/E =0.65/√E, ∆Eabs=2% Forward Neutron Tracker (FNT) Sc hodoscope @ 1λint, σx,y=0.23cm, σθ=22μrad Leading Proton Spectrometer (LPS) Six stations with silicon μ-strip detectors σxL < 1%, σpT 5 MeV H1: similar devices pT resolution limited by beam spread: 50 MeV horizontal, 100MeV vertical • Data samples: • neutron: 0.2<xL<1, θn<0.75mrad pT2 < 0.476 xL2 GeV2 • proton: 0.56<xL, pT2 varying with xL between pT2 <0.15 and <0.5 GeV2 • DIS (ep Xn): 40pb-1, Q2>2GeV2 • PHP (γp Xn): 6pb-1, Q2<0.02 GeV2 • di-jets in PHP (γp jjXn): 40pb-1, Q2<1GeV2, 130<W<280GeV, ETj1>7.5GeV, ETj2>6.5, -1.5<ηj1,2<2.5
D’Alesio & Pirner: PHP DIS σ~Wα, α(σγp) α(σγ*p) & Wπ2=(1-xL)Wp2 (1-xL) -0.1 • LN yield in PHP < yield in DIS factorization violation • Models in agreement with data ! Leading neutrons: xL spectrum DIS • LN yield increases with xL due to increase in phase space: pT2 < 0.476 xL2 • LN yield decreases for xL1 due to kinematic limit
Leading Neutrons: pT2 spectra in DIS DIS • Exponential behavior with slope b • Intercept and exponential slope fully characterize the pT2 spectra
pT2<0.04 DIS • Iso-spin Clebsch-Gordan for pure iso-vector exchange: expect rLP=1/2 rLN • but rLP > rLN other additional exchanges needed in LP Leading Neutrons: pT2 spectra intercept pT2=0 DIS • intercept ~ cross section integrated over all pT2 rise towards low xL
Leading Neutrons: b - slopes One Pion Exchange Model: xL π ´,n s´= (cm energy of eπ system )2 fπ/p= pion flux factor exponential fit b-slopes in data not described by the b-slopes in the models.
slopes different in PHP and DIS • in general agreement with expectation from absorption more absorption @ small rnπ depletion @ large pT steeper slope in PHP Leading Neutrons: b-slopes in PHP & DIS normalized @ pT2=0
Leading Neutrons & Protons: b-slopes • slopes almost flat for LP (different additional exchanges) • visible decrease for xL1 in LP can be due to changing acceptance of LPS in pT2 for increasing xL(for small pT2 slope seems steeper as for larger pT2)
Predictions from Theory (KMR) • Including other iso-vector exchanges, like ρ and a2, • additional exchanges increase the cross section (e.g. for xL) • but they decrease the b-slopes • difficult to describe all dependencies simultaneously
Predictions from Theory (KMR) p p,r,a2 Other exchanges flatten the pT2 distributions in both, a bit more in PHP than in DIS In summary: adjustment of all available parameters with the precise leading baryon data gives not only valuable information for the absorptive effects at work in exclusive Higgs-production @ LHC, but also determines the fluxes and the measurement of F2π.
Lepto+MEPS best for xL spectra, but flat b-slope, • Lepto+Ariadne, RAPGAPin standard mode, CASCADE cannot describe any of the distributions: too few neutrons, too low xL, b-slopes too flat. • Same situation for leading protons ! • But: good MC description crucial Leading Neutrons: Comparisons to MC Assuming the leading baryon production proceeds via the standard fragmentation process do standard MC generators describe the data ?
Factorization in PHP di-jets with LN ? resolved PHP DIS direct PHP xobs Re-scattering processes expected for resolved PHP: photon acts hadron-like additional interactions between remnants and scattered partons absorption (see also diffractive di-jets in PHP, previous talk) Relevant variable: xγ momentum fraction of the photon entering the hard sub-process.
H1: RAPGAP/PYTHIA-MI (Eur. Phys. J. C41 (2005) 273-286 ) not ok ok Factorization in PHP di-jets with LN ? ZEUS: RAPGAP/HERWIG-MI (Nucl.Phys.B596,3(2001)) not ok ok No possibility to decide on factorization breaking due to re-scattering processes in resolved PHP (xγ<1) with hadron-like photon.
Summary • a lot more, new and precise, leading baryon data available from HERA • precise input for the determination the pion-flux and the pion structure function • indications for absorption/migration observed • theory provides now a lot of predictions can be used to further tune the absorption factors expected for the discovery channel of exclusive Higgs production @ LHC • MC generators in general not describing the data need to understand the process of leading baryon production and the implementation of its mechanism in the generators. Even in this old and traditional high energy physics topic a lot remains still to be understood which has direct impact on the physics @ LHC