Structure Functions and Parton Distribution Functions at the HERA ep Collider

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Structure Functions and Parton Distribution Functions at the HERA ep Collider by Chris Targett Adams (University College London) on behalf of the ZEUS and H1 collaborations. Moriond QCD, 16/03/2005

Contents Today we'll be covering the following topics Introduction to HERA physics & kinematics ep cross sections and structure functions Applications of HERA structure function data Measurements of F 2, xf 3 and F L HERA QCD fits Summary

Introduction to HERA Physics HERA is the largest of the particle accelerator rings operated by DESY (Hamburg,Germany) The world's only ep collider. 90% of the delivered luminosity between 93 04 has been with e + Currently delivering e luminosity ZEUS and H1 are two general purpose experiments located on the HERA ring 27.5GeV e /+ 920(820)GeV p

Introduction to HERA Kinematics / Z 0 exchange Neutral Current (NC) W ± exchange Charged Current (CC) s=320 300 GeV Q 2 q 2 = k k ' 2 CMS energy virtuality Q 2 1GeV 2 Q 2 1GeV 2 Deep Inelastic Scattering (DIS) Photoproduction x= Q2 2 P p q y= P p q P p k ' Fraction of proton's momentum carried by the struck parton Fraction of lepton's energy transferred to the proton Q 2 =sxy Y ± =1± 1 y 2

ep Cross Sections and Structure Functions d 2 NC e ± p dxdq 2 = 2 2 [Y xq 4 F 2 x,q 2 y 2 F L x,q 2 Y F 3 x,q 2 ] Modified at high Q 2 by Z 0 propagator. d 2 CC e ± p dxdq 2 = G 2 2 F M W [Y 2 x M 2 W Q 2 2 W ± 2 x,q 2 y 2 W ± L x,q 2 Y W ± 3 x,q 2 ] HERA inclusive data provides valuable information on sea and valence quarks. Gluons probed indirectly via scaling violations and directly via jet data. F 2 xq i x q i xf 3 xq i x q i F L s xg x,q 2 {similarly for Dominant contribution Sensitive at high Q 2 Sensitive at high Q 2 & high y W±2, xw±3 and W±L. d 2 CC e p [ u c 1 y 2 d s ] }Sensitive to u dxdq 2 and d valence d 2 CC e p quarks at LO [ u c 1 y 2 d s ] dxdq 2

The Importance of HERA Data Q 2 dependence is directly calculable using pqcd (DGLAP) x dependence has to be determined empirically Measure cross sections > perform fits HERA PDFs extrapolate into LHC region Crucial in calculations of new physics and measurements at LHC

Precision F 2 Data NC = Q2 x 2 2 1 Y d 2 dxdq 2 Reduced cross section =F 2 when F L xf 3 0 Range in x : 0.00001 1 Range in Q 2 ~ 1 30000GeV 2 Measured with ~2 3% precision Directly sensitive to sum of all quarks and anti quarks Indirectly sensitive to gluons via scaling violations.

H1 Measurement of F L Here we discuss the 'Shape method'. r =F 2 x,q 2 y2 F Y L x,q 2 For fixed s and Q 2 very distinct overlap in r observed at low x, or high y (Q 2 =sxy). At fixed Q 2, F 2 parameterised as cx and F L assumed to be constant across the region of overturn i.e. F 2 =cx and F L x,q 2 F L Q 2 Therefore, fit f y = cx y2 Y F L Q 2 with measured r (y) to find F L (Q 2 ) At presently reached accuracy F L data is reasonably well described by NLO QCD in which the gluon distribution is determined from the scaling violations of F 2

ZEUS Measurement of F L The only way to measure F L directly is to make measurements of r at fixed x and Q 2 but differing values of y. F L can then be disentangled from F 2 r =F 2 x,q 2 y2 Y F L x,q 2 ISR reduces s At fixed x and Q 2, y is different Changes contribution of F 2 and F L. Measure r vs y and fit for F L. Measurement only made in one Q 2 bin. Measurement is not very precise but is clearly consistent with the expectations of pqcd.

High Q 2 NC Cross Sections At high Q 2 NC cross sections for e + and e deviate ± NC F 2 Y xf Y 3 Subtract NC positron from electron cross section High Q 2 NC cross sections directly sensitive to different species of valence quark Errors dominated by statistical error of the e sample Need greater luminosity Currently running with e

QCD fits General method Parameterize PDFs at some starting scale Q 0 2 Evolve to arbitrary Q 2 using DGLAP Calculate cross sections and compare to data Iteratively change the starting parameters until best fit is found HERA QCD fits A brief history Performed by both H1 and ZEUS, broadly compatible Valence quarks constrained by heavy target data ( Fe and D) World F 2 data used > Many different experiments, not just HERA Inclusive cross sections indirectly sensitive to gluon (scaling violations) S and gluon strongly correlated via DGLAP > poor S and gluon extraction dq i x,q 2 dlnq 2 = Q 2 s 1 2 x dy y [ j q j y,q 2 P j x qi q y g y g,q2 P x ] qi y HERA QCD fits New developments High Q 2 NC and CC data constrain valence quarks > No fixed target data Exclusive (Jet) cross sections tie down the gluon, accurate determination of S. Fits done entirely with HERA data, no external experiments

ZEUS QCD fits Jet Data QCDC BGF QCD Compton and Boson Gluon fusion processes give rise to events with distinct jets in the final state. QCDC depends on S & q i (x,q 2 ), dominates at hard scales. q i (x,q 2 ) well constrained from NC and CC data. Thus, at hard scales S may be extracted without strong correlation to g(x,q 2 ) Further, BGF depends directly on g(x,q 2 ) and provides a means to constrain the gluon DIS inclusive jets p dijets

HERA QCD fits Extracted PDFs ZEUS and H1 PDFs broadly consistent HERA PDFs consistent with those of MRST and CTEQ

ZEUS QCD fits Impact of Jet Data Jet data has a significant impact on the precision of the extracted gluon PDF. MRST and CTEQ also include jet data in their fits (High E T Tevatron jet data), however the cross sections are included using approximate techniques. ZEUS utilizes a rigorous method of including jet data in its fits.

HERA QCD fits Determination of S s = 0.1150±0.0017 exp ±0.0007 model H1 s = 0.1183±0.0028 exp ±0.0008 model ZEUS Scale uncertainty = ±0.005 Quite large but would significantly improve with NNLO fits

Summary HERA continues to produce important research on proton structure and provide a stringent testing ground for QCD PDFs and s can be extracted with minimal data from external experiments Rigorous inclusion of jet data into the fitted data sets leads to a significantly more precise gluon PDF and s to be extracted from HERA data alone HERA II measurements already reaching publication stage Luminosity has now been collected with 0, ( ) and (+) polarisation First measurement of the helicity structure of CC interactions with a space like gauge boson

Future Plans HERA II program well underway > Increased statistics > even more precise cross section measurements Currently running with electrons > More precise electron NC and CC cross sections > More precise extraction of xf 3 Combination of ZEUS and H1 data sets to produce Global HERA fits NNLO QCD fits Inclusion of more exclusive data in to the fitted data sets: heavy flavor cross sections, optimized jet cross sections etc Possible dedicated reduced E p (still in the early stages of deliberation) running periods allowing a direct measurement of F L Thank you for paying attention! Any queries, please contact us target@mail.desy.de

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