tensor and flavor-singlet axial charges and their scale dependencies
DESCRIPTION
Tensor and Flavor-singlet Axial Charges and Their Scale Dependencies. Hanxin He China Institute of Atomic Energy. Contents. 1. Introduction: Quark distribution functions and their first moments--- nucleon’s charges 2 . Tensor charges and their scale dependencies - PowerPoint PPT PresentationTRANSCRIPT
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Tensor and Flavor-singlet Axial Charges and Their
Scale Dependencies
Hanxin He
China Institute of Atomic Energy
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Contents
1. Introduction: Quark distribution functions and their first moments--- nucleon’s charges
2. Tensor charges and their scale dependencies * Theory estimates of tensor charges * Perturbative QCD evolutions * Non-perturbative evolutions from model calculation3. Flavor singlet axial charge and its scale dependence * Perturbative QCD evolution * Nonperturbative evolution due to PCAC4. Comparing the scale dependencies of tensor and fla
vor singlet (scalar) axial charges5. Summary
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1. Introduction:
The quark-gluon structure of nucleon is described by a set of parton distribution functions.
• The helicity and transversity distributions and their first moments--- the axial and tensor charges provide important information on the nucleon spin structure.
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• Since the tensor current is not conserved, the tensor charge defined by the matrix element of tensor current is strong scale dependent especially at low-energy region.
• The axial current is conserved in the DIS region where the quark mass can be neglected, thus the flavor singlet (scalar) axial charge has weak scale dependence due to the couping with gluon at NLO perturbation QCD evolution.
• However the scale dependence of the flavor singlet (scalar) axial charge in low-energy region may be strong due to PCAC.
• How to study the scale dependencies of these charges in low energy region ?
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Quark distribution functions at leading twist
Longitudinally polarized Transversely polarized
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Quark distribution functions at leading twist.1
Where q_f(x) ---find a quark parton probability in a nucleon
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Quark distribution functions at leading twist.2
The transversity distributions measure the difference of number of quarks(antiquarks) with transverse polarization parallel and antiparallel to the nucleon likewise polarized
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Helicity distributions and their first moments---axial charges
* Where flavor singlet axial charge in MS frame gives the quark spin contribution to nucleon’s spin
=1.2601
=0.588
( Flavor singlet )
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Transversity distributions and their first moments--- tensor charges
The flavor singlet tensor charge and isovector tensor charge can be defined
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2. Tensor Charges and their scale dependencies
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Theory estimates of tensor charges—model calculation results
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Separation of Collins, Sivers and pretzelocity effects through angular dependence in SIDIS
1( , )
sin( ) sin( )
sin(3 )
l lUT h S
h SSiverCollins
Pretzelosi
UT
tyU
sUT h S
h ST
N NA
P N
A
A
N
A
1
1 1
1
1 1
sin( )
sin(3 )
sin( )Co
PretzelosityU
SiversUT
llins
T h S T
h S
UT
UT h S
TU
UT
TA
H
f
A
D
A h H
h
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Measurements of transversity distributions and tensor charges
• Jlab measured the single target spin asymmetry(SSA) in SIDIS
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A Global Analysis of Experimental Data
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Experimental extraction of tensor charges
• Extraction of tensor charges was given by Anselmino et al. based on the combined global fit to semi-inclusive DIS(SIDIS) data from HERMES and COMPASS and those in (BELLE)
The results are(central values)
( From Phys.Rev.D75,054032(2007; arXiv:0809.3743 )
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Scale dependence of tensor Charge:
• QCD perturbative evolutions
Note that gluons do not enter the evolution equation for transversity distributions due to the chiral-odd property.
The evolution equation of tensor charge at leading order
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* Perturbutive evolutions of tensor cha
rges to next leading order(NLO)
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Perturbative evolution (to NLO)of flavor singlet tensor charge
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* How to describe scale dependencies of tensor charges
in low-energy region ?
• Lattice QCD.
We use:
• Effective quark model of tensor charges
• Cooperating with dynamically quark mass generating to account nonperturbative QCD effects
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* Effective theory analysesQCD at low-energy is equivalent to an effective quark theory
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Transversity distributions and tensor charges are
valence quark dominated since
• Tensor current operator is odd under charge conjugation----the quark-antiquark sea does not contribute
• Gluons do not contribute under QCD evolution of trensversity distributions
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Axial charges and tensor charges in the effective theory
where
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Axial and tensor charges in the effective quark picture
Where m is dynamical quark mass
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*Nonperturbative evolution: Effective theory analyses of tensor charges
• Here m is dynamical quark mass.• Generally one may set definite m to calculate the matrix
element.• The quark mass in QCD is a running quantity, different
mass corresponds to different scale.• Flavor singlet tensor charge of current quark
contributions (in the asymptotic limit)
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Running quark mass: Scale evolutions of quark mass
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Scale dependencies of tensor charges for u- and d-quarks
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Scale dependencies of isovector- and isoscalar tensor charges
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3. Flavor singlet axial charge and its scale dependence
• In MS frame the flavor singlet axial charge gives quark spin contribution to nucleon spin
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*Axial charges and quark spin contribution to nucleon spin
• Nucleon spin sum rules
All components are scale-dependent
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* Nucleon spin sum rules--satisfying angular momentum
commutation relation
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Quark spin contribution to nucleon spin
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Unpolarized and Polarized Structure functions
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Quark spin contribution to nucleon spin
The measurement results are given at Q^2 =5 Gev^2
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Perturbative Evolutions of QCD angular momentum operators
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* Scale dependence of flavor singlet axial charge due to PCAC
---the axial-vector current operator is not
conserved if m does not equal to 0.
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*Flavor singlet (scalar) axial chargein effective quark model
Which is well agreement with the results given by HERMES & COMPASS groups.
The current quark (m=0) spin contribution to nucleon spin is
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Scale evolution of quark spin contribution to nucleon spin
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Flavor singlet axial charge
Flavor singlet tensor charge
Isovector tensor charge
4.Comparing scale dependence of tensor charge with that of axial charge
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Scale dependencies of scalar tensor and axial charges
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5. Summary(1)
• Tensor charges are most important quantities that characterize transversities
• Tensor charges are strong scale dependent, especially in the low-energy region.
• Using the quark model in cooperation with dynamical quark mass generating can reasonably describe the scale dependencies from perturbation to nonperturbation region, while the results are well consistent with the QCD perturbation evolution ones in the large momentum region.
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Effective model predicts
• In the asymptotic limit, present effective quark model predicts that tensor charges are
For proton
For neutron
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5. Summary(2)
• Flavor singlet (scalar) axial charge is one of most important quantities that characterize helicity, which in the MS scheme gives quark spin contribution to nucleon spin
• Flavor singlet (scalar) axial charge in DIS region has weak scale dependence due to the coupling with gluon at NLO perturbation QCD evolution. However, the flavor singlet (scalar) axial charge in the low-energy region is strong scale dependent due to
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5. Summary(3)• PCAC and dynamical chiral symmetry breaking, which c
an be reasonably described by using the quark model in cooperation with dynamical quark mass generating.
• This effective model also predicts that the quark spin contributes to 1/3 of nucleon spin in large momentum limit, which is well consistent with HERMES & COMPASS results.
• Comparing the scale evolutions of the flavor singlet (scalar) axial and tensor charges shows that relativistic effects lead to the difference between them: Relativistic effect on scalar axial-charge is larger then one on scalar tensor charge.
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Thank you