lawrence berkeley national laboratory · ¨ form factors behavior ... n asymptotic freedom and...
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7/14/18 1
Standard Parton Physics
Feng Yuan Lawrence Berkeley National Laboratory
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Outline
n Review earlier lectures (in particular, by JP Ma) and introduction
n Introduce GPDs, connection to TMDs, and Wigner Distribution
n Small-x physics
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n Parton Physics ¨ G. Sterman, Partons, Factorization and
Resummation, hep-ph/9606312 ¨ John Collins, The Foundations of Perturbative QCD,
published by Cambridge, 2011 ¨ CTEQ, Handbook of perturbative QCD, Rev. Mod.
Phys. 67, 157 (1995).
n General references ¨ CTEQ web site:
http://www.phys.psu.edu/~cteq/
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Rutherford scattering
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Discovery of Nuclei
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Power counting analysis
n EM interaction perturbation, leading order dominance, potential~1/r
n Point-like structure n Powerful tool to study inner structure
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Momentum Transfer q
k k�
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Basic idea of nuclear science
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670 Prof. E. Rutherford on the
ext)lain tile scattering of'electrlfled particles in passing through small thicknesses of matter. The atom is supposed to consist of a number N of negatively charged corpuscles, accompanied by .m equal quantity of positive electricity uniformly dis- trihuted throughout a sphere. The deflexion of a negatively electrified ),article in passing th,'ough the atom is ascribed to two causes--t1) the repulsion of tile corpuscles distributed through the atom, and (2) the attraction of the positive electricitv in the atom. The deflexion of the particle in passing through the atom is supposed to be small, while the average deflexion after a large number m of encounters was (.aken as ~/m. O, where i9 is the average deflexion due to a single atom. I t was shown that the number N of the electrons within the atom could be deduced from observations of the scattering of electrified particles. The accuracy of tiffs theory of compound scattering was examined experimentally by Crowther + in a later paper. His results apparently confirmed the main conclusions of the theory, and b.e deduced, on the assumption that the positive electricity was continuous, that the number of electrons in an atom was about three times its atomic weight.
The theory of Sir J . J . Thomson is based on the assumption that the scat.tering due to a single atomic encounter is small, and the particular structure assumed for the atom does not admit of a very large deflexion of an a particle in traversing a single atom, unless i~ be supposed that the diameter of the sphere of positive electricity is minute compared with the diameter or' the sphere of influence of the atom.
Since the a and/~ particles traverse the atom, i t should be possible from a close study of the nature of the deflexion to form some idea of the constitution of the atom to produce the effects observed. In fact, the scattering of high=speed charged particles by the atoms of matter is one of the most promising methods of attack of this problem. The develop= ment of the scintillation method of counting single ~ particles affords unusual advantages of in vestigation, and the researches of H. Geiger by this method have already added much to our knowledge of the scattering of a rays by matter.
w 2. We shall first examine theoretically the single en- counters t with an atom of simple structure, which is able to
* Crowther, Proe. Roy. See. lxxxiv, p. 226 (1910). t The deviation of a'partiele throughout a considerable angle from
an encounter with a single atom will in this paFer be called " single" scattering. The devb~t[on of a particle resulting from a multitude of small deviation~ will be termed "compound " scattering.
Rutherford, 1911
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Finite size of nucleon (charge radius) n Rutherford scattering with electron
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Hofstadter
Renewed interest on proton radius: µ-Atom vs e-Atom (EM-form factor)
RevModPhys.28.214
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Quark model n Nucleons, and other hadrons are not
fundamental particles, they have constituents
n Gell-Man Quark Model ¨ Quark: spin ½
n Charges: up (2/3), down (-1/3), strange (-1/3)
¨ Flavor symmetry to classify the hadrons n Mesons: quark-antiquark n Baryons: three-quark n Gell-Man-Okubo Formula
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Gell-Man
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Deep Inelastic Scattering
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Friedman Kendall Taylor
Bjorken Scaling: Q2àInfinity Feynman Parton Model: Point-like structure in Nucleon
Discovery of Quarks
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Understanding the scaling n Weak interactions at high momentum
transfer ¨ Rutherford formula rules
n Strong interaction at long distance ¨ Form factors behavior ¨ No free constituent found in experiment
n Strong interaction dynamics is different from previous theory
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QCD and Strong-Interactions n QCD: Non-Abelian gauge theory
¨ Building blocks: quarks (spin½, mq, 3 colors; gluons: spin 1, massless, 32-1 colors)
n Asymptotic freedom and confinement
1( )4
aq a sL i m F F g Aµν
µνψ γ ψ ψγ ψ= ⋅∂ − − − ⋅
Clay Mathematics Institute Millennium Prize Problem
Long distance:? Soft, non-perturbative
Nonperturbative scale ΛQCD~1GeV ~1/Length
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Quantum Chromodynamics
n There is no doubt that QCD is the right theory for hadron physics
n However, many fundamental questions… n How does the nucleon mass? n Why quarks and gluons are confined inside the nucleon? n How do the fundamental nuclear forces arise from QCD? n We don’t have a comprehensive picture of the nucleon
structure as we don’t have an approximate QCD nucleon wave function
n …
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Feynman’s parton language and QCD Factorization
n If a hadron is involved in high-energy scattering, the physics simplifies in the infinite momentum frame (Feynman’s Parton Picture)
n The scattering can be decomposed into a convolution of parton scattering and parton density (distribution), or wave function or correlations ¨ QCD Factorization!
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High energy scattering as a probe to the nucleon structure
n Many processes: Deep Inelastic Scattering, Deeply-virtual compton scattering, Drell-Yan lepton pair production, ppàjet+X ¨ Momentum distribution: Parton Distribution ¨ Spin density: polarized parton distribution ¨ Wave function in infinite momentum frame: Generalized Parton
Distributions
DVCS
Drell-Yan
Hadronic reactions
DIS
(Q>>ΛQCD)
k Feynman Parton Momentum fraction
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n Future facilities ¨ Jlab@12GeV ¨ JPARC (Japan) ¨ GSI-FAIR (Germany) ¨ EIC, LHeC, …
Exploring the partonic structure of nucleon worldwide
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DESY
CERN,LHC COMPASS Jefferson Lab
RHIC@BNL
SLAC
Fixed Target & Tevatron@FermiLab Belle@KEK
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Perturbative Computations n Singularities in higher order calculations n Dimension regularization
¨ n<4 for UV divergence ¨ n>4 for IR divergence ¨ MS (MS) scheme for UV divergence
n pQCD predictions rely on Infrared safety of the particular calculation
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pQCD predictions n Infrared safe observables
¨ Total cross section in e+e-àhadrons ¨ EW decays, tau, Z, …
n Factorizable hard processes: parton distributions/fragmentation functions ¨ Deep Inelastic Scattering ¨ Drell-Yan Lepton pair production ¨ Inclusive process in ep, ee, pp scattering, W,
Higgs, jets, hadrons, … 7/14/18 19
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n Leading order
¨ Electron-positron annihilate into virtual photon, and decays into quark-antiquark pair, or muon pair
¨ Quark-antiquark pair hadronize
Infrared safe: e+e-àhadrons
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p1
p2 q
k1
k2
electron
positron
quark
antiquark
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Long distance physics (factorization)
n Not every quantities calculated in perturbative QCD are infrared safe ¨ Hadrons in the initial/final states, e.g.
n Factorization guarantee that we can safely separate the long distance physics from short one
n There are counter examples where the factorization does not work
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Naïve Parton Model
n the parton distribution describes the probability that the quark carries nucleon momentum fraction
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n In the Bjorken limit, nucleon is Lorentz contracted
Intuitive argument for the factorization (DIS)
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k
xP
k
xP
Hadron wave function scale ~ 1/Lambda ~1/GeV
Hard interaction scale ~ 1/Q
k�
Hadronization scale ~1/GeV
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Factorization formula
n Factorization à scale dependence
n Scale dependence à resummation
anomalous dimension: 7/14/18 24
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Quark-quark splitting
n Physical polarization for the radiation gluon n Incoming quark on-shell, outgoing quark off-shell
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Quark-gluon splitting
n Incoming quark on-shell, gluon is off-shell
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Gluon-quark splitting
n Incoming gluon is on-shell, physical polarization
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Gluon-gluon splitting
n Physical polarizations for the gluons
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These evolutions describe the HERA data
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CTEQ6
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Reverse the DIS: Drell-Yan
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J.C. Peng
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Drell-Yan lepton pair production
n The same parton distributions as DIS ¨ Universality
n Partonic cross section
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Profound results
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u Universality u Perturbative QCD at work
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More general hadronic process
n All these processes have been computed up to next-to-leading order, some at NNLO, few at N3LO
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Hadronic reactions
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PDG2014
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Parton picture of the nucleon
n Beside valence quarks, there are sea and gluons n Precisions on the PDFs are very much relevant
for LHC physics: SM/New Physics
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C.-P.Yuan@DIS15
DIS summary
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36 Proton Spin
Parton distribution when nucleon is polarized?
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n The story of the proton spin began with the quark model in 60�s
n In the simple Quark Model, the nucleon is made of three quarks (nothing else)
n Because all the quarks are in the s-orbital, its spin (½) should be carried by the three quarks
n European Muon Collaboration: 1988 �Spin Crisis�--- proton spin carried by
quark spin is rather small
u d u
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Parton distributions in a polarized nucleon
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Quark Helicity Gluon Helicity
RHIC DIS
de Florian-Sassot-Stratmann-Vogelsang, 2014
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Proton spin: emerging phenomena?
n We know fairly well how much quark helicity contributions, ΔΣ=0.3±0.05
n With large errors we know gluon helicity contribution plays an important role
n No direct information on quark and gluon orbital angular momentum contributions
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The orbital motion: n Orbital motion of quarks and gluons must
be significant inside the nucleons! ¨ This is in contrast to the naive non-relativistic
quark model n Orbital motion shall generate direct orbital
Angular Momentum which must contribute to the spin of the proton
n Orbital motion can also give rise to a range of interesting physical effects (Single Spin Asymmetries)
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New ways to look at partons n We not only need to know that partons
have long. momentum, but must have transverse degrees of freedom as well
n Partons in transverse coordinate space ¨ Generalized parton distributions (GPDs)
n Partons in transverse momentum space ¨ Transverse-momentum distributions (TMDs)
n Both? Wigner distributions!
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q Wigner distributions (Belitsky, Ji, Yuan)
Unified view of the Nucleon
5D
3D
1D
(X. Ji, D. Mueller, A. Radyushkin)
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Zoo of TMDs & GPDs
γ,h
GPDs
h
TMDs
§ NOT directly accessible § Their extractions require measurements of x-sections and
asymmetries in a large kinematic domain of xB, t, Q2 (GPD) and xB, PT, Q2 , z (TMD)
k
k k
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What can we learn n 3D Imaging of partons inside the nucleon
(non-trivial correlations) ¨ Try to answer more detailed questions as
Rutherford was doing 100 years ago n QCD dynamics involved in these processes
¨ Transverse momentum distributions: universality, factorization, evolutions,…
¨ Small-x: BFKL vs Sudakov?
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Deformation when nucleon is transversely polarized
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Lattice Calculation of the transvese density Of Up quark, QCDSF/UKQCD Coll., 2006
Quark Sivers function fit to the SIDIS Data, Anselmino, et al. 2009
k y
kx
-0.5
0.5
0.0
-0.5 0.0 0.5
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Parton’s orbital motion through the Wigner Distributions
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Phase space distribution: Projection onto p (x) to get the momentum (probability) density Quark orbital angular momentum
Well defined in QCD: Ji, Xiong, Yuan, PRL, 2012; PRD, 2013 Lorce, Pasquini, Xiong, Yuan, PRD, 2012 Lorce-Pasquini 2011 Hatta 2011
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Where can we study: Deep Inelastic Scattering
n Inclusive DIS ¨ Parton distributions
n Semi-inclusive DIS, measure additional hadron in final state ¨ Kt-dependence
n Exclusive Processes, measure recoiled nucleon ¨ Nucleon tomography
47
H1&ZEUS@HERA HERMES
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What we have learned n Unpolarized transverse momentum
(coordinate space) distributions from, mainly, DIS, Drell-Yan, W/Z boson productions, (HERA exp.)
n Indications of polarized quark distributions from low energy DIS experiments (HERMES, COMPASS, JLab)
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What we are missing n Precise, detailed, mapping of polarized
quark/gluon distribution ¨ Universality/evolution more evident
n Spin correlation in momentum and coordinate space/tomography ¨ Crucial for orbital motion
n Small-x: links to other hot fields (Color-Glass-Condensate)
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Perspectives n HERA (ep collider) is limited by the
statistics, and is not polarized n Existing fixed target experiments are
limited by statistics and kinematics n JLab 12 will provide un-precedent data
with high luminosity
n Ultimate machine will be the Electron-Ion-Collider (EIC): kinematic coverage with high luminosity
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We need a new machine: EIC Proposals in US
51
arXiv: 1108.1713, arXiv: 1212.1701
high luminosity & wide reach in √s
polarized lepton & hadron beams
nuclear beams
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PROTON SPIN
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Proton Spin n Emerging property of the fundamental
building block of the universe ¨ Spin sum rule in parton model and QCD ¨ Exp. vs Lattice
n Emerging phenomena ¨ Parity violating, electro-weak interaction, SM ¨ (naïve) time-reversal odd Single trandverse
spin asymmetries ¨ Under extreme conditions: small vs large x
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54 7/15/18
Ultimate goal of spin physics?
n Spin sum rule
Quark spin, Best known Gluon spin,
Start to know Orbital Angular Momentum of quarks and gluons, Little known
Jaffe-Manohar, 90 Ji, 96
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EMC experiment at CERN n Polarized muon + p deep inelastic scattering,
¨ Virtual photon can only couple to quarks with opposite spin, because of angular momentum conservation
¨ Select q+(x) or q-(x) by changing the spin direction of the nucleon or the incident lepton
¨ The polarized structure function measures the quark spin density
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Summary of the polarized DIS data
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dxΔg ~ 0.10.05
0.2
∫
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How to access the OAM
n Generalized Parton Distributions n Transverse Momentum Dependent
Distributions n Wigner Distributions
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59 7/16/18
n A new type of parton “distributions” contains much more information ¨ Can be measured in deeply
virtual compton scattering and other hard exclusive processes
¨ Related to form factors and parton distributions
Hunting for Lq: Generalised Parton Distributions (GPDs)
Mueller et al., 94; Ji, 96; Radyushkin, 96
DIS DVCS
Parton Distributions
Generalized Parton Distributions
30%(DIS) ∫ ( H + E) x dx = Jq = 1/2 ΔΣ + Lz Ji,96
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General Comments
n Gauge invariant n Frame independent n Works for L/T polarizations of nucleon n Physical accessible
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Proton spin decomposition n Angular momentum density à spin vector
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Angular momentum density
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n Partonic interpretation works in the infinite momentum frame (IMF)
n In this frame, the leading component is P+,S+
n Next-to-leading component, ST
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Leading component M++T
n Because of antisymmetric of α,β. The leading term is α=+,β=T, which related to the transverse spin of the nucleon
n Transverse spin of nucleon has leading-twist interpretation in parton language
n However, individual spin is obscure
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Next-to-leading: M+TT
n Because of two transverse indices, it inevitably involves twist-three operators
n However, it does lead to the individual spin contribution, e.g., from the quark ¨ Jaffe-Manohar spin decomposition
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Angular Momentum density (T) n Define the momentum density
n AM depending momentum fraction x,
Which gives the angular momentum density for quark with longitudinal momentum x
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In more detail
n Calculate ρ+(x,ξ,ST)
n Integrate out ξ, second term drops out, we obtain the momentum density
n Integral with weight ξT’, the first term drops out, à Angular Momentum density
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Longitudinal (helicity)
n Quark spin explicitly n OAM, twist-three nature
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Wigner function: Phase Space Distributions n Define as
¨ When integrated over x (p), one gets the momentum (probability) density
¨ Not positive definite in general, but is in classical limit
¨ Any dynamical variable can be calculated as
∫= ),(),(),( pxWpxdxdpOpxO
Wigner 1933
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Wigner distribution for the quark n The quark operator
n Wigner distributions After integrating over r, one gets TMD After integrating over k, one gets Fourier
transform of GPDs
Ji: PRL91,062001(2003)
single quantum oscillator, the classical limit is not straightforward. The Wigner distributionfor the n-th excited state is
W (n; x, p) = [(�1)n/(⌅h)] exp[�2H(x, p)/h⌃]L(0)n [4H(x, p)/(h⌃)] (15)
where L(0)n is a Lagurre polynomial. In the limit that h ⇤ 0, the Wigner distribution has
essential singularities. If n is fixed, the distribution becomes
limh⇥0
W (n; x, p) = �(x)�(p) (16)
which corresponds classically to a harmonic oscillator at rest. If E stays finite in the classicallimit, then W oscillates widely. But if we regard it as a distribution, one does recover theclassical average for observables.
Other definitions of the phase-space distributions are possible, for example, Husimi andKirkwood distributions. Together, they are called the Cohen class phase-space distributions.The Husimi distribution is obtained as a square of the wave function amplitudes in thecoherent state and hence is real. All these distributions reduced to classical phase-spacedistribution in the h⇤ 0 limit.
B. Quark Wigner Disitruitons in the Nucleon
The quark Wigner distributions were introduced in Ref. [5]. Here we provide moreexplanation why the specific construction was made there. In quantum field theory, quarkwave function is replaced by quark field, and it is natural to introduce the Wigner operator,
W�(⇠r, k) =
⇤⇥(⇠r � ⇥/2)�⇥(⇠r + ⇥/2)eik·�d4⇥ , (17)
where ⇠r is the quark phase-space position and k the phase-space four-momentum. � is aDirac matrix defining the types of quark denstities.
Since QCD is a gauge theory, the two quark fields at di⇤erent spacetime points are notautomatically gauge-invariant. One can define a gauge-invariant quark field by adding agauge link to the spacetime infinity along a constant four-vector nµ,
⇥(⇥) = exp
��ig
⇤ ⇤
0
d⇤n · A(⇤n + ⇥)
⇥⇧(⇥) , (18)
where we assume the non-singular gauges in which the gauge potential vanish at the space-time infinity.
We have extended the Wigner distribution to include the time variable. Therefore, besidethe dependence on the three-momentum, there is also dependence on the energy. For thesimple bound states such as those in an harmonic oscillator, the energy dependence is simplya � function at the binding energy. For many-body system, the energy-dependence is morecomplicated.
For non-relativistic systems for which the center-of-mass is well-defined and fixed, one canget the Wigner distribution by taking the expectation value of the above Wigner operator.As we have explained in Sec. II, it is more complicated for the nucleon for which the motion
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Importance of the gauge links
n Gauge invariance n Depends on the processes n Comes from the QCD factorization
n And partonic interpretation as well
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Fixed point gauge link
n Becomes unit in ξ.A=0 gauge n Moment gives the quark OAM
n OPE
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Quark OAM
n Any smooth gauge link results the same OAM for the partons
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Light-cone gauge link
n it comes from the physical processes ¨ DIS: future pointing ¨ Drell-Yan: to -∞
n Cautious: have light-cone singularities, and need to regulate
n Moments related to twist-three PDFs, and GPDs
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Light-cone decomposition
n Quark OAM only contains the partial derivative
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Gauge Invariant Extension
n GIE is not unique
n Canonical OAM can be calculated
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OAM from Wigner distribution
n Can be measured from hard processes n Moments access to the canonical OAM n In the end of day, depends on twist-3
GPDs ¨ Might be studied in many processes
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Wigner Distributions
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xq(x, µ) =1
✏U.V.�Q
2s ln
µ
2
Q
2s+ finite terms
�(�⇤T p)|Q2!0 /1
✏I.R.� ln
µ
2
Q
2s+ · · ·
H(~r?,~k?) =Z
dxdzW (~r, x, k?)
K(~r?) =Z
d
2k?~k?H(~r?,~k?)
1
Define the net momentum projection
Quark oribital angular momentum
xq(x, µ) =1
✏U.V.�Q
2s ln
µ
2
Q
2s+ finite terms
�(�⇤T p)|Q2!0 /1
✏I.R.� ln
µ
2
Q
2s+ · · ·
H(~r?,~k?) =Z
dxdzW (~r, x, k?)
K(~r?) =Z
d
2k?~k?H(~r?,~k?)
Lq =Z
d
2r?d
2k?~r? ⇥ ~
k?H(~r?,~k?)
1
Lorce, Pasquini, arXiv:1106.0139 Lorce, Pasquini, Xiong, Yuan, arXiv:1111.482 Hatta, arXiv:1111.3547
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OAMs: Light-cone Wave Functions n They are building blocks for the hadron
structure
n Which can be used to calculate the integrated parton distributions, GPDs, and hard exclusive scattering amplitudes, including the Compton scattering amplitudes
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General Structure n Starting from any general structure for
a Fock state, lz+λ=Λ, with lz=∑i=1n-1lzi
n We will get
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Asymptotic Behavior n The asymptotic behavior for the light-
cone wave function can be studied from hard diagrams
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Nucleon’s 3-quarks WF n According to the general structure,
there are six independent light-cone wave functions for three quarks component: Lz=0 (2), Lz=1 (3), Lz=2 (1)
n The power counting rule gives, asymptotically,
ψ |lz=0~ 1/kT4
ψ |lz=1~ 1/kT6
ψ |lz=2~1/kT8
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Three Quark Light Cone Amplitudes
6 independent wave function amplitudes:
Isospin symmetry
parity time reversal
total quark helicity Jq
v classification of LCWFs in angular momentum components
Jz = Jzq + Lz
q
[Ji, J.P. Ma, Yuan, 03; Burkardt, Ji, Yuan, 02]
Lzq =2 Lz
q =1 Lzq =0 Lz
q = -1
Lzq = 1 Lz q= 0 Lz
q = 2 Lzq
= -1
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Quark OAM (Jaffe-Manohar)
n Definition
n Using light-cone quantization
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Distribution in x of Orbital Angular Momentum
Definition of Jaffe and Manohar: contribution from different partial waves
Comparison between the results with the Jaffe-Manohar definiton and the results with the Ji definition (total results for the sum of up and down quark contribution)
up down
Lz=0 Lz=-1
Lz=+2 Lz=+1
Ji
Jaffe-Manohar
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Orbital Angular Momentum
Definition of Jaffe and Manohar: contribution from different partial waves
Definition of Ji:
= 0 x 0.62 + (-1) x 0.14 + (+1) x 0.23 + (+2) x 0.018 = 0.126
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Wigner Distribution W(x,r,kt)
Transverse Momentum Dependent PDF f(x,kt)
Generalized Parton Distr. H(x,ξ,t)
d2 kt
PDF f(x)
dx
Form Factors F1(Q),F2(Q)
GPD
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TMD Parton Distributions n The definition contains explicitly
the gauge links
n The polarization and kt dependence provide rich structure in the quark and gluon distributions
¨ Mulders-Tangerman 95, Boer-Mulders 98
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Collins-Soper 1981, Collins 2002, Belitsky-Ji-Yuan 2002
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Generalized Parton Distributions
n Off-diagonal matrix elements of the quark operator (along light-cone)
n It depends on quark momentum fraction x and skewness ξ, and nucleon momentum transfer t
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Mueller, et al. 1994; Ji, 1996, Radyushkin 1996