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Physics with H1 at HERA II
Max Klein DESY Zeuthen ? HERA and the H1 experiment Inclusive deep inelastic scattering and jets Low x and the evolving view on parton dynamics Further new physics Leave searches, pdf‘s, electroweak, ... for RY MK - H1 in HERA II, Ringberg Workshop, October 2nd, 2003
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HERA H1 goals for HERA II High luminosity: 1fb-1 e+ and e-, polarised
change of Ep MK - H1 in HERA II,
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HERA and the LHC QCD, searches, p structure 4pi multipurpose detectors
MK - H1 in HERA II,
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(Upgrades of) the H1 Detector for HERA II
36 institutes, 320 authors 210 postdocs data taking since 1992 Fast Track Trigger Very Forward Proton Spectro- meter VFPS Luminosity spectrometer e p 27.5 GeV 920 GeV Forward tracking: Si + DC MK - H1 in HERA II,
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yp e‘ p e e+ LAr calorimeter DIS
2. Inclusive Deep Inelastic Scattering and Jets deep inelastic neutral current scattering event in the H1 apparatus yp Spacal p e‘ e 27.5 GeV 920 GeV Silicon Strips Drift chambers e+ LAr calorimeter DIS s=4EeEp= GeV2 MK - H1 in HERA II,
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Inclusive jets: well described by NLO QCD
event shapes & QCD resummed Inclusive jets: well described by NLO QCD MK - H1 in HERA II,
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HERA II HERA I you can never have enough luminosity
500pb-1 e+ 500pb-1 e- expected HERA I 100pb-1 e+ 15pb-1 e- measured g-Z interference: e- constructive / e+ destructive pb-1: 10 % cross section error for Q2 > GeV2 you can never have enough luminosity to beat 1/Q^4 and (1-x)^3 MK - H1 in HERA II,
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Charged currents HERA II
Unfolding of parton distributions using CC and NC cross sections difficult to reach very large x>0.7 reduced cc cross section 2500 GeV2 700 GeV2 e+, 250pb-1 7000 GeV2 25000 GeV2 e-, 250pb-1 _ _ --- s (e-p) ~ x (u+c) + (1-y2) x (d+s) --- s (e+p) ~ x (u+c) + (1-y2) x (d+s) x x MK - H1 in HERA II,
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simulations: x helicity suppression in charged currents
e+ beam polarisation measured in February 2003 helicity suppression in charged currents simulations: x MK - H1 in HERA II,
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parity violation in neutral currents
simulation x singlet MK - H1 in HERA II,
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DIS measurement of alpha_s - with H1 and BCDMS data
± (exp+fit) ± (ren.scale) joint determination of alphas, xg, V,A no interest in quarks two pdfs only 9 F2 = 3 xV +11xA = 4xU+xD chi2+1 well defined two consistent exp data sets MK - H1 in HERA II,
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the BCDMS data determines all DIS determinations of the strong coupling,
BUT shifts imposed by QCD fit to BCDMS data alphas (BCDMS) very low and strongly y dependent („electron method“) low y – large x region in conflict with SLAC F2 systematic errors of BCDMS data MK - H1 in HERA II,
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run at minimum possible proton beam energy
access large x at lower Q2 x=0.07 simulation 460 GeV*27.5 GeV 30 pb-1 x=0.10 x=0.14 W2=20GeV x=0.18 x=0.23 x=0.25 x=0.35 x=0.45 x=0.55 Measurements at low y: Simulation of resonance region Low noise calorimetry Forward tracking BCDMS data x=0.65 y=0.3 at 280 GeV MK - H1 in HERA II,
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Correlation of alphas and xg is resolvable in DIS fits with HERA data
determination of alphas and of the gluon distribution inclusive DIS fits yield very small gluon density at large x must fail to describe Tevatron jets MK - H1 in HERA II,
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3. Low x and the evolving view on parton dynamics
high density low x and parton emission diffraction heavy flavours skewed parton distributions MK - H1 in HERA II,
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strong scaling violations at low x lead to very large gluon momentum density
xg depends on c treatment! xg is not an observable no unique determination and still uncertain at low x, Q2! Higher precision, more constraints (FL, charm, J/Psi and Y ~ xg2) MK - H1 in HERA II,
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simulation of low Ep data [~ 460, 575, 920 GeV]
HERA II simulation Longitudinal structure function H1 prel simulation of low Ep data [~ 460, 575, 920 GeV] MK - H1 in HERA II,
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forward jet and particle production
forward jets in BFKL region DIS: Q2 >5 GeV2 dijets: azimuthal decorrelation NLO 3-jets in trouble at lowest x CCFM (unintegrated g) and CDM ok x MK - H1 in HERA II,
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Diffractive ep Scattering: large and puzzling part of the cross section
Smashed in DIS but “intact” in diffraction ? MK - H1 in HERA II,
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concept works in charm and jet production in ep
MK - H1 in HERA II,
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…it doesnt at the Tevatron
HERA II …it doesnt at the Tevatron H1: extended instrumentation of upstream p beam region spectator i.a.’s break p? soft colour interactions? G.Ingelman Blois 03 MK - H1 in HERA II,
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Deeply Virtual Compton Scattering
NLO LO beautiful events, signature interferes with Bethe Heitler e Colour Dipol Models Generalised Parton Distributions MK - H1 in HERA II,
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beam spin asymmetry pol. e beams
ALU ~ sign(e) • Im (BH•DVCS*) sin Φ beam charge asymmetry e+-e- AC ~ Re (BH•DVCS*) cos Φ Map proton wave function in DIS (large Q2) region and at low x (cf HERMES) Access to H structure function angular momentum part of proton spin (Ji) A.Freund hep-ph/ MK - H1 in HERA II,
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theory of heavy flavour production
HERA II mid x (CST), extend to low x (BST) and large x (FST) high statistics through luminosity upgrade and Fast Track Trigger for photoproduced charm requires further theoretical development (NLO) MK - H1 in HERA II,
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simulation 200pb-1 MK - H1 in HERA II,
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run at minimum possible proton beam energy
measure energy (W) dependence of cross sections, VM production … run at minimum possible proton beam energy MK - H1 in HERA II,
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High statistics and precision Lifetime tags
HERA II High statistics and precision Lifetime tags MK - H1 in HERA II,
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Summary HERA has dramatically expanded our view on the
structure of the proton and the strong interactions yet We still don’t know well enough xg at low and large x, alpha_s, uv, dv, s, c, b in HERA’s range How to formulate the theory of DIS at high parton densities The nature of diffraction or heavy flavour production We have just started to explore Beauty physics Correlations between (within) diffraction, HQ and jets Generalised parton distributions Extreme regions of phase space (hi t, hi pt, hi x) We will open new fields with much increased luminosity, polarisation and changed beam energies such as searches, collider (single) spin physics, elw. space like physics… We need HERA longer than currently envisaged to study Confinement (low x,Q2), saturation (eA), neutron structure (eD), spin MK - H1 in HERA II,
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Summary MK - H1 in HERA II,
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