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A20121 Parton Distribution Functions, Part 1 Daniel Stump Department of Physics and Astronomy Michigan State University A.Introduction B.Properties of.

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Presentation on theme: "A20121 Parton Distribution Functions, Part 1 Daniel Stump Department of Physics and Astronomy Michigan State University A.Introduction B.Properties of."— Presentation transcript:

1 A20121 Parton Distribution Functions, Part 1 Daniel Stump Department of Physics and Astronomy Michigan State University A.Introduction B.Properties of the PDFs C.Results of CT10-NNLO Global Analysis D.Uncertainties of the PDFs E. Applications to LHC Physics

2 A20122 A. Introduction. QCD and High-Energy Physics QCD is an elegant theory of the strong interactions – the gauge theory of color transformations. It has a simple Lagrangian (sums over flavor and color are implied) Parameters: g; m 1, m 2, m 3, …, m 6 Introduction

3 A20123 However, the calculation of experimental observables is quite difficult, for 2 reasons: (i) there are divergent renormalizations; the theory requires  regularization  perturbation theory  a singular limit    (GeV) or, a  0 (fm) or, n  4 (ii) quark confinement; the asymptotic states are color singlets, whereas the fundamental fields are color triplets. Introduction

4 A20124 Nevertheless, certain cross sections can be calculated reliably --- --- inclusive processes with large momentum transfer (i.e., short-distance interactions) The reasons that QCD can provide accurate predictions for short-distance interactions are  asymptotic freedom  s (Q 2 ) ~ const./ln(Q 2 /  2 ) as Q 2    the factorization theorem d  hadron ~ PDFs  C where C is calculable in perturbation theory. The PDFs provide a connection between quarks and gluons (the partons) and the nucleon (a bound state). Introduction

5 A20125 Global Analysis of QCD and Parton Distribution Functions d  hadron ~ PDFs  C (sum over flavors implied) The symbol ~ means “asymptotically equal as Q   ”; the error is O(m 2 /Q 2 ) where Q is an appropriate (high) momentum scale. The C’s are calculable in perturbation theory. The PDFs are not calculable today, given our lack of understanding of the nonperturbative aspect of QCD (binding and confinement). But we can determine the PDFs from Global Analysis, with some accuracy. Introduction

6 A20126 next …

7 B120127 B. Properties of the PDFs -- Definitions First, what are the Parton Distribution Functions? (PDFs) The PDFs are a set of 11 functions, f i (x,Q 2 ) where longitudinal momentum fraction momentum scale f 0 = g(x,Q 2 ) the gluon PDF f 1 = u(x,Q 2 ) the up-quark PDF f -1 = u(x,Q 2 ) the up-antiquark PDF f 2 = d and f -2 = d f 3 = s and f -3 = s etc. - - - parton index Exercise: What about the top quark? Properties of the PDFs

8 B120128 Second, what is the meaning of a PDF? We tend to think and speak in terms of “Proton Structure” u(x,Q 2 ) dx = the mean number of up quarks with longitudinal momentum fraction from x to x + dx, appropriate to a scattering experiment with momentum transfer Q. u(x,Q 2 ) = the up-quark density in momentum fraction This heuristic interpretation makes sense from the LO parton model. More precisely, taking account of QCD interactions, d  proton = PDFs  C. Properties of the PDFs

9 B120129 f i (x,Q 2 ) = the density of parton type i w.r.t. longitudinal momentum fraction x valence up quark integral, valence down quark integral, valence strange quark integral Properties of the PDFs longitudinal momentum fraction, carried by parton type i Momentum Sum Rule Flavor Number Sum Rules

10 B1201210 Example. DIS of electrons by protons; e.g., HERA experiments (summed over flavors!) in lowest order of QCD Properties of the PDFs

11 B1201211 But QCD radiative corrections must be included to get a sufficiently accurate prediction. The NLO approximation will involve these interactions … From these perturbative calculations, we determine the coefficient functions C i (NLO), and hence write Approximations available today: LO, NLO, NNLO Properties of the PDFs

12 B1201212 The Factorization Theorem For short-distance interactions, and the PDFs are universal ! We can write a formal, field-theoretic expression, although we can’t evaluate it because we don’t know the bound state |p>. Properties of the PDFs Correlator function

13 B1201213 Exercise. Suppose the parton densities for the proton are known, (A) In terms of the f i (x,Q 2 ), write the 11 parton densities for the neutron, say, g i (x,Q 2 ). (B) In terms of the f i (x,Q 2 ), write the 11 parton densities for the deuteron, say, h i (x,Q 2 ). Properties of the PDFs

14 B1201214 next …

15 B2201215 B. Properties of the PDFs – Q 2 evolution Evolution in Q The PDFs are a set of 11 functions, f i (x,Q 2 ) where longitudinal momentum fraction momentum scale f i (x,Q 2 ) = the density of partons of type i, carrying a fraction x of the longitudinal momentum of a proton, when resolved at a momentum scale Q. The DGLAP Evolution Equations  We know how the f i vary with Q.  That follows from the renormalization group.  It’s calculable in perturbation theory. Q 2 evolution

16 B2201216 The DGLAP Evolution Equations V.N. Gribov and L.N. Lipatov, Sov J Nucl Phys 15, 438 (1972); G. Altarelli and G. Parisi, Nucl Phys B126, 298 (1977); Yu.L. Dokshitzer, Sov Phys JETP 46, 641 (1977). Solve the 11 coupled equations numerically. For example, you could download the program HOPPET. G. P. Salam and J. Rojo, A Higher Order Perturbative Parton Evolution Toolkit; download from http://projects.hepforge.org/hoppet … a library of programs written in Fortran 90. Q 2 evolution

17 B2201217 Q 2 evolution

18 B2201218 Some informative results obtained using HOPPET Starting from a set of “benchmark input PDFs”, let’s use HOPPET to calculate the evolved PDFs at selected values of Q. For the input (not realistic but used here to study the evolution qualitatively): Output tables Q 2 evolution

19 B2201219 The Running Coupling of QCD Q 2 evolution  S (Q 2 ) Q 2 evolution

20 B2201220 The QCD Running Coupling Constant For Global Analysis, we need an accurate  S (Q 2 ). Q 2 evolution (approx. : N F = 5 massless)

21  S (M Z ) = 0.1184  0.0007 S. Bethke, G. Dissertori and G.P. Salam; Particle Data Group 2012 B2201221 The QCD Running Coupling Constant Evolution of  S as a function of Q, using the 1-loop beta function (red) the 2-loop beta function (green) the 3-loop beta function (blue) For Global Analysis, we need an accurate  S (Q 2 ). Q 2 evolution

22 B2201222 The QCD Running Coupling Constant How large are the 2-loop and 3-loop corrections for  S (Q 2 )? Q 2 evolution

23 B2201223 Comments on  S (Q 2 )  An important improvement is to include the quark masses.  The central fit has  S (M Z ) = 0.118. (Bethke)  CTEQ also provides alternative PDFs with a range of value of  S (M Z ); these are called the  S -series.  Another approach is to use the Global Analysis to “determine” the value of  S (M Z ).  Asymptotic freedom Q 2 evolution

24 B2201224 Examples from HOPPET U-quark PDF evolution : Black : Q = Q 0 = 1.414 GeV Blue : Q = 3.16 GeV (1-loop, 2-loop, 3-loop) Red : Q = 100.0 GeV (1-loop, 2-loop, 3-loop) How does the u-quark PDF evolve in Q? Q 2 evolution

25 B2201225 Gluon PDF evolution : Black : Q = Q0 = 1.414 GeV Blue : Q = 3.16 GeV (1-loop, 2-loop, 3-loop) Red : Q = 100.0 GeV (1-loop, 2-loop, 3-loop) Examples from HOPPET How does the gluon PDF evolve in Q? Q 2 evolution

26 B2201226 DGLAP evolution of PDFs  The “structure of the proton” depends on the resolving power of the scattering process. As Q increases … PDFs decrease at large x PDFs increase at small x as we resolve the gluon radiation and quark pair production.  The momentum sum rule and the flavor sum rules hold for all Q.  These graphs show the DGLAP evolution for LO, NLO, NNLO Global Analysis. Q 2 evolution

27 B2201227 How large are the NLO and NNLO corrections? … a good exercise using HOPPET Q 2 evolution

28 B2201228 Q 2 evolution next …

29 B3201229 Structure of the Proton CTEQ Parton Distribution Functions CTEQ6.6 P. M. Nadolsky, H.-L. Lai, Q.-H. Cao, J. Huston, J. Pumplin, D. Stump, W.-K. Tung, C.-P. Yuan, Implications of CTEQ global analysis for collider observables, Phys.Rev.D78:013004 (2008) ; arXiv:0802.0007 [hep-ph] CT10 Hung-Liang Lai, Marco Guzzi, Joey Huston, Zhao Li, Pavel M. Nadolsky, Jon Pumplin, C.-P. Yuan, New parton distributions for collider physics, Phys.Rev.D82:074024 (2010) ; arXiv:1007.2241 [hep-ph] CT10-NNLO (2012) The results shown below are for CT10-NNLO. CT10-NNLO PDFs

30 B3201230 Structure of the Proton The U Quark (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Red: u(x,Q 2 ) Dashed Red: ū(x,Q 2 ) Gray: u valence (x,Q 2 ) This log-log plot shows … … for x ≳ 0.1 the valence structure dominates … for x ≲ 0.01 ū approaches u CT10-NNLO PDFs

31 B3201231 Structure of the Proton The U Quark (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Red: x u(x,Q 2 ) Dashed Red: x ū(x,Q 2 ) Gray: x u valence (x,Q 2 ) This linear plot shows the momentum fraction for Q = 3.16 GeV (= area under the curve) integral ≈ 0.32, 0.05, 0.27 CT10-NNLO PDFs

32 B3201232 Structure of the Proton The U Quark (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Red: u valence (x,Q 2 ) This linear plot demonstrates the flavor sum rule: integral = 2 CT10-NNLO PDFs

33 B3201233 Structure of the Proton The D Quark (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Blue: d(x,Q 2 ) Dashed Blue: đ(x,Q 2 ) Gray: d valence (x,Q 2 ) This log-log plot shows … … for x ≳ 0.1 the valence structure dominates … for x ≲ 0.01 đ approaches d CT10-NNLO PDFs

34 B3201234 Structure of the Proton The D Quark (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Blue: d(x,Q 2 ) Dashed Blue: đ(x,Q 2 ) Gray: d valence (x,Q 2 ) This linear plot shows the momentum fraction for Q = 3.16 GeV (= area under the curve) integral ≈ 0.15, 0.06, 0.10 CT10-NNLO PDFs

35 B3201235 Structure of the Proton The D Quark (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) d valence = d – đ (x,Q 2 ) This linear plot demonstrates the flavor sum rule: integral = 1 CT10-NNLO PDFs

36 B3201236 This linear plot compares U and D -- quarks and antiquarks; naively, d = 0.5 u, but it’s not that simple. Structure of the Proton The D and U Quarks (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Blue: d(x,Q 2 ) Dashed Blue: đ(x,Q 2 ) Gray: d valence (x,Q 2 ) Red: u(x,Q 2 ) Dashed Red: ū(x,Q 2 ) Gray: u valence (x,Q 2 ) CT10-NNLO PDFs

37 B3201237 Structure of the Proton The D and U Quarks (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) d(x,Q 2 ) / u(x,Q 2 ) v x d(x,Q 2 ) / u(x,Q 2 ) is interesting. Exercise: What scattering processes could provide information on this ratio? CT10-NNLO PDFs

38 B3201238 Structure of the Proton Gluons (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) black : g(x,Q 2 ) red : u(x,Q 2 ) The gluon dominates at small x. The valence quarks dominate at large x. CT10-NNLO PDFs

39 B3201239 Structure of the Proton Gluons (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) black : g(x,Q 2 ) red : u(x,Q 2 ) blue: d(x,Q 2 ) The gluon dominates at small x. The valence quarks dominate at large x. CT10-NNLO PDFs

40 B3201240 Structure of the Proton Sea Quarks and Gluons (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) sea(x,Q 2 ) and g(x,Q 2 ) vs x black: g(x,Q 2 ) brown: sea(x,Q 2 ) sea = 2 (db + ub + sb) CT10-NNLO PDFs

41 B3201241 Structure of the Proton (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) Ratios : (db, ub, sb)/g CT10-NNLO PDFs Exercises: (1) Identify db, ub, sb. (2) Why are they all equal at small x?

42 B3201242 Structure of the Proton (Q 2 = 10 GeV 2 ; Q = 3.16 GeV) All in One Plot u_valence d valence sea * 0.05 gluon * 0.05 CT10-NNLO PDFs Sea = 2 (db + ub + sb) u_valence = u – ub ; u = u_valence + u_sea ub = u_sea

43 B3201243 Structure of the Proton … as a function of Q All in One Plot u_valence d valence sea * 0.05 gluon * 0.05 CT10-NNLO PDFs Sea = 2 (db + ub + sb) u_valence = u – ub ; u = u_valence + u_sea ub = u_sea

44 B3201244 Exercise: (A) Use the Durham Parton Distribution Generator (online PDF calculator) to reproduce these graphs. (B) Show the Q 2 evolution. CT10-NNLO PDFs

45 B3201245 next …

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