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XXXIII International Conference of Theoretical Physics

XXXIII International Conference of Theoretical Physics. MATTER TO THE DEEPEST: Recent Developments in Physics of Fundamental Interactions, USTROŃ'09 . Ustron , Poland September 11-16, 2009 .

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XXXIII International Conference of Theoretical Physics

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  1. XXXIII International Conference of Theoretical Physics MATTER TO THE DEEPEST: Recent Developments in Physics of Fundamental Interactions, USTROŃ'09 Ustron, PolandSeptember 11-16, 2009

  2. HamzehKhanpourIn collaboration with:Ali Khorramian, ShahinAtashbarTehraniSemnan UniversityandSchool of Particles and Accelerators, IPM (Institute for Studies inTheoretical Physics and Mathematics), Tehran, IRAN Determination of valence quark densities up to higher order of perturbative QCD HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  3. Outline • Abstract • Introduction • DIS Kinematics • Parton distributions and hard processes (1,2) • What we need for 4-loop calculations? • Splitting functions and Coefficient functions • Pade’ approximate • The method of the QCD analysis of Structure Function • The procedure of the QCD fits of F2 data • Results and Conclusion HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  4. Abstract • We present the results of our QCD analysis for non-singlet unpolarized quark distributions and structure function F2(x,Q2) up to N3LO. The analysis is based on the Jacobi polynomials technique of reconstruction of the structure functions from its Mellin moments. • The fit results for the non-singlet parton distribution function, their correlated errors and evolution are presented. Our results on and strong coupling constant up to N3LO are presented and compared with those obtained from deep inelastic scattering processes. In the N3LO analysis, the QCD scale and the strong coupling constant were determined with the help of Pade-approximation. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  5. Introduction • Complete knowledge of the parton distributions in the nucleon is essential for calculating deep inelastic processes at high energies. • All calculations of high energy processes with initial hadrons, whether within the standard model or exploring new physics, require parton distribution functions (PDF's) as an essential input. The assessment of PDF's, their uncertainties and extrapolation to the kinematics relevant for future colliders such as the LHC is an important challenge to high energy physics in recent years. • Parton distributions form indispensable ingredients for the analysis of all hard-scattering processes involving initial-state hadrons. • Presently the next-to-leading order is the standard approximation for most important processes but the N2LO and N3LO corrections need to be included, however, in order to arrive at quantitatively reliable predictions for hard processes at present and future high-energy colliders. • For quantitatively reliable predictions of DIS and hard hadronic scattering processes, perturbative QCD corrections beyond the next-to-leading order, N2LO and N3LO, need to be taken into account. • For at least the next ten years, proton (anti-) proton colliders will continue to form the high-energy frontier in particle physics. At such machines, many quantitative studies of hard (high mass/scale) standard-model and new-physics processes require a precise understanding of the parton structure of the proton. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  6. DIS Kinematics The deep-inelastic lepton-nucleon scattering is the source of important information about the nucleons structure. The negative four momentum transfer squared at the electron vertex The Bjorken scale variable x and the inelasticity y Deep inelastic scattering in the quark parton model. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  7. Parton distributions and hard processes (1) At zeroth order in the strong coupling constant the hard coefficient functions ca,iare trivial, and the momentum fraction carried by the struck quark i is equal to Bjorken-x if mass effects are neglected. inclusive photon-exchange deep-inelastic scattering (DIS) In general, the structure functions are given by HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  8. Parton distributions and hard processes (2) Parton distributions fi: evolution equations (⊗ = Mellin convolution) The initial conditions are not calculable in perturbative QCD. The task of determining these distributions can be divided in two steps. The first is the determination of the non-perturbative initial distributions at some (usually rather low) scale Q0. The second is the perturbative calculation of their scale dependence (evolution) to obtain the results at the hard scales Q. The initial distributions have to be fitted using a suitable set of hard-scattering observables. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  9. Procedure Determination of the parton density functions from experimental data is according to the following procedure: The parton density functions are parameterised by smooth analytical functions at a low starting scale Q02 as a function of x with a certain number of free parameters.They are evolved in Q2 using the DGLAP equations.Afterwards predictions for structure functions and cross-sections are calculated. The free parameters are determined by performing a fit to the data.Several constraints are imposed during this procedure. For an accurate determination of the parton density functions the coefficient and splitting functions have to be precisely known as they govern the calculation of the structure functions and the evolution, respectively. Since 2005 all of them are known to next-to-next-to-leading order (N2LO). HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  10. what we need for 4-loop calculations? The splitting functions P(n) and the process-dependent hard coefficient functions ca admit expansions in powers of strong coupling constant The first n+1 terms define the NnLO approximation. N2LO: N3LO: HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  11. Splitting functions and Coefficient functions The complete NNLO splitting functions and coefficient functions are known [J. A. M. Vermaseren, A. Vogt and S. Moch, Nucl. Phys. B 724 (2005) 3] [S. Moch, J. A. M. Vermaseren and A. Vogt, Nucl. Phys. B 688 (2004) 101] The 3-loop coefficient functions are known [J. A. M. Vermaseren, A. Vogt and S. Moch, Nucl. Phys. B 724 (2005) 3] In spite of the unknown 4–loop splitting functions one may wonder whether any statement can be made on the non–singlet parton distributions and at the 4–loop level !!!!!!! HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  12. The answer is: Pade’- approximate [M.A. Samuel, J. Ellis and M. Karliner, Phys. Rev. Lett. 74 (1995) 4380. ] [J. Ellis, E. Gardi, M. Karliner and M.A. Samuel, Phys. Lett. B366 (1996) 268. ] [J. Ellis, E. Gardi, M. Karliner and M.A. Samuel, Phys. Rev. D54 (1996) 6986. ] HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  13. Coefficient functions Pade’ [0/2] Pade’ [1/1] Padé estimates for the large-N behaviour of the three-loop contributions to the non-singlet coefficient function C2,ns(N). The three-loop approximants are compared with exact results. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  14. The perturbative expansion of the non-singlet N-space coefficient functions HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  15. Pade’ [0/2] 4-loop Splitting functions Pade’ [1/1] HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  16. The perturbative expansion of the anomalous dimension HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  17. The method of the QCD analysis of SF One of the simplest and fastest possibilities in the structure function reconstruction from the QCD predictions for its Mellin moments is Jacobi polynomials expansion. [ A. N. Khorramian and S. A. Tehrani, Phys. Rev. D 78 (2008) 074019. ] [ S. Atashbar Tehrani and A. N. Khorramian, JHEP 0707 (2007) 048 ] HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  18. Structure function in x space F2 Structure function as extracted from the DIS ep process can be, up to N3LO written as The combinations of parton densities in the non-singlet regime and the valence region x>0.3 for F2p and F2d in LO is In the region x<0.3 for the difference of the proton and deuteron data we use HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  19. The evolution equations are solved in Mellin-N space and the Mellin transforms of the above distributions are denoted by respectively. The non–singlet structure functions are given by Here denotes the strong coupling constant and are the non–singlet Wilson coefficients in HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  20. The solution of the non–singlet evolution equation for the parton densities to 4–loop order reads Here, denote the Mellin transforms of the (k + 1)–loop splitting functions. [ A. N. Khorramian and S. A. Tehrani, Phys. Rev. D 78 (2008) 074019. ] [J. Blumlein, H. Bottcher and A. Guffanti, Nucl. Phys. B 774, 182 (2007)]

  21. The procedure of the QCD fits of F2 data In the present analysis we choose the following parameterization for the valence quark densities By QCD fits of the world data for , we can extract valence quark densities using the Jacobi polynomials method. For the non-singlet QCD analysis presented here we use the structure function data measured in charged lepton proton and deuteron deep-inelastic scattering. [ A. N. Khorramian and S. A. Tehrani, Phys. Rev. D 78 (2008) 074019. ] [J. Blumlein, H. Bottcher and A. Guffanti, Nucl. Phys. B 774, 182 (2007)] HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  22. Results

  23. [ A. N. Khorramian and S. A. Tehrani, Phys. Rev. D 78 (2008) 074019. ] [J. Blumlein, H. Bottcher and A. Guffanti, Nucl. Phys. B 774, 182 (2007)] HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  24. Fit results Table: Parameters values of the LO, NLO,NNLO and N3LO non-singlet QCD fit at Q02 = 4 GeV2 HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  25. Parton densities at the input scale Q02 = 4 GeV2 Comparison of the parton densities xuvand xdvat the input scale Q02 = 4 GeV2 and at different orders in QCD as resulting from the present analysis. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  26. [J. Blumlein, H. Bottcher and A. Guffanti, Nucl. Phys. B 774, 182 (2007)] The parton densities xuvand xdvat the input scale Q02 = 4 GeV2(solid line) compared to results obtained from N3LO analysis by BBG (dashed line). HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  27. The parton densities xuv(x,Q2) and xdv(x,Q2) at N3LO evolved up to Q2 = 10000 GeV2(solid line) compared to results obtained by BBG (dashed line). HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  28. The structure functions F2pand F2das function of Q2 in intervals of x. Shown are the pure QCD fit in N3LO (solid line) and the contributions from target mass corrections TMC (dashed line) and higher twist HT (dashed–dotted line). The arrows indicate the regions with W2 >12.5 GeV2. The shaded areas represent the fully correlated 1σ statistical error bands.

  29. The structure function F2NSas function of Q2in intervals of x. Shown is the pure QCD fit in N3LO (solid line).

  30. Conclusion • We performed a QCD analysis of the non–singlet world data up to N3LO and determined the valence quark densities xuv(x,Q2) and xdv(x,Q2) with correlated errors. • Parameterizations of these parton distribution functions and their errors were derived in a wide range of x and Q2 as fit results at LO, NLO, NNLO, and N3LO. • In the analysis the QCD scale and the strong coupling constant αs(M2Z), were determined up to N3LO. • In spite of the unknown 4–loop splitting functions we applied Pade’-approximate for determination of non–singlet parton distributions and QCD at the 4–loop level. • Our calculations for non-singlet unpolarized quark distribution functions based on the Jacobi polynomials method are in good agreement with the other theoretical models. HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

  31. Thanks to attention !! HamzehKhanpour (IPM & Semnan University) hamzeh_khanpour@nit.ac.ir USTRON 2009

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