Deeply Virtual Compton Scattering Studies with CLAS and CLAS12
description
Transcript of Deeply Virtual Compton Scattering Studies with CLAS and CLAS12
Thomas Jefferson National Accelerator FacilityPage 1 August 8, 2011
Deeply Virtual Compton Scattering Studies with CLASCLAS and CLAS12CLAS12
Latifa ElouadrhiriJefferson Lab
t
CLASCLAS
CLAS12CLAS12
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GGeneralized eneralized PPartonartonDDistributionsistributions(GPDs)(GPDs)
The size and structure of proton.Proton form factors, transversecharge and current distributionsNobel prize 1961- R. Hofstadter
Internal constituents of the nucleonQuark longitudinal momentum and helicity distributionsNobel prize 1990 - J. Friedman, H. Kendall, R. Taylor
GPDs connect the quark distribution in transverse space and longitudinal
momentum
D. Mueller, X. Ji, A. Radyushkin,(1994-1997),… M. Burkardt, A. Belitsky (2000)…
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Deeply Virtual Compton Scattering & GPDsDeeply Virtual Compton Scattering & GPDs
GPDs depend on 3 variables, e.g.H(x, , t).They describethe internal nucleon dynamics.
Deeply Virtual Compton Scattering (DVCS)
t
x+ x-
hard vertices
– longitudinal momentum transfer
x – longitudinal quark momentum fraction
–t – Fourier conjugateto transverse impact parameter
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Link to DIS and Elastic Form Factors
),,(~,~,, txEHEH qqqq
DIS at =t=0
)()0,0,(~)()0,0,(
xqxH
xqxHq
q
Form factors (sum rules)
)(),,(~,)(),,(~
)Dirac f.f.(),,(
,
1
1,
1
1
1
tGtxEdxtGtxHdx
tF1txHdx
qPq
qAq
q
q
)Pauli f.f.(),,(1
tF2txEdxq
q
J G = 1
1
)0,,q()0,,q(21
21 xE xHxdxJ q
X. Ji, Phy.Rev.Lett.78,610(1997)
Angular Momentum Sum Rule
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Physical content of GPD E&H
M2(t) : Mass distribution inside the nucleonJ (t) : Angular momentum distribution d1(t) : Forces and pressure distribution
Nucleon matrix element of the Energy-Momentum Tensor of QCD contains 3 scalar form factor:
GPDs are related to these form factors through 2nd moments
Directly measured in elasticgraviton-proton scattering!
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AccessingGPDsThrough DVCS
d4dQ2dxBdtd
~ |TDVCS + TBH|2
DVCS BH
Eo = 11 GeV Eo = 6 GeV Eo = 4 GeV
BH
DVCS
GPDs are universal, they can be determined in any suitable process
TBH: given by elastic form factorsTDVCS: determined by GPDs
BH-DVCS interference generates beam and target asymmetries that carry the nucleon structure information.
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1
1
1
1
),,(),,(
~),,(
~ tHidxx
txHPdx
ix
txHT DVCS
Cross-sectionmeasurementand beam charge asymmetry (ReT)integrateGPDs over x
Beam or target spin asymmetrycontainonlyImT,thereforeGPDsatx = and -
(at leading order:)
GPDs& DVCS
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Accessing GPDsthrough polarization
LU~ sinIm{F1H+ (F1+F2)H+kF2E}d~
Polarized beam, unpolarized target:
Unpolarized beam, longitudinal target:
UL~ sinIm{F1H+(F1+F2)(H+/(1+)E) -.. }d~
Unpolarized beam, transverse target:
UT~ cosIm{k(F2H– F1E) + ….}d
= xB/(2-xB)
k = t/4M2
H
Kinematically suppressed
Kinematically suppressed
H~
KinematicallysuppressedH, E
A =
=
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First observation of DVCS/BH beam asymmetry
Early GPD analysis of CLAS/HERMES/HERA data in LO/ NLO shows results consistent with handbag mechanism and lowest order pQCD. A. Freund (2003), A. Belitsky, et al. (2003)
sin + sin2
<< 1 twist-3 << twist-2
e+pe+X e-p e-pX
CLAS4.3 GeV
2001
0
HERMES27 GeV
-180 +180(deg)
Q2=2.5 GeV2
Q2=1.5 GeV2
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First DVCS measurement with spin-aligned target
Unpolarized beam, longitudinally spin-aligned target:
UL~ sinIm{F1H+(F1+F2)H+…}d~
= 0.252 ± 0.042 = -0.022 ± 0.045
CLAS preliminary
H=0~
H=0~
AUL is dominated by Hand H ~
fitmodelmodel (H=0)
~
S. Chen, et al., Phys. Rev. Lett 97, 072002 (2006)
CLAS
Consistent with leading twist
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Hall A
First Dedicated DVCS Experiments at JLab
Azimuthal and Q2 dependence of Im(TDVCS) at fixed x.Test Bjorkenscaling.
Full reconstruction of all final state particles e, p, High luminosity
x, t, Q2 - dependence of Im(TDVCS) in wide kinematics. Constrain GPD models.
PbWO4
Electromagneticcalorimeter
s.c.solenoid
CLAS
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Results of the Hall A DVCS experiment
Phys.Rev.Lett.97:262002,2006
First absolute cross section measurements in the valence quark regime.
Verify Bjorken scaling of cross section in limited Q2 range.
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Results of the CLAS E1-DVCS experiment
Beam-spin asymmetries
Phys.Rev.Lett.100:162002,2008
LU~ sin{F1H+ (F1+F2)H+kF2E}d
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GPD extraction from truncated expansion (H only)
H. Moutarde, Phys.Rev.D79:094021, 2009
Truncation allows analysis of x and t dependences of H, but neglecting H is problematic.~
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Extractions of GPDs from full expansion
A nearly model-independent GPD analysis in leading twist has become possible due the availability of beam-spin and target-spin asymmetry results at 3 values of t and fixed x.
•HIm drops with t similar to VGG model but has smaller magnitude• H-tilde tends to be larger than model prediction
M. Guidal, Phys.Rev.Lett. B689:156-162,2010
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CLAS12 - DVCS – Dedicated longitudinally polarized target experiment
To extend GPD extraction from polarization data improvement of statistics and expansion of kinematical coverage is needed.
Pioneering results from data mining
Preliminary data from eg1-dvcs experiment have 10 times previous statistics
AU
L
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CLAS12 - DVCS with transversely polarized target
Transverse asymmetries AUT and ALT are sensitive to GPD E. GPDs E and H enter in the angular momentum sum rule.
A precise measurement of AUT will help resolve the proton spin puzzle.
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JLab Upgrade to 12 GeV
CHL-2CHL-2
Enhance equipment in existing halls
Add new Add new hallhall
At 12 GeV, CEBAF is an ideal laboratory for GPD studies in the valence quark regime.
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CLAS will be replaced with CCLAS12LAS12
CLAS12CLAS12is designed to operate with order of magnitude higher luminosity.
CLAS12CLAS12designed to accommodate polarized solid state targets NH3, ND3 and HD.
Hall B 12GeV upgrade overview from Hall B 12GeV upgrade overview from CLAS CLAS to to CLAS12CLAS12
Present DayCLAS
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Kinematic reach of the 12 GeV Upgrade
H1, ZEUS
11 GeV
H1, ZEUS
JLab @ 12 G
eV
27 G
eV
200
GeV
Study of high xB domain requires high luminosity
0.7
HERMES
COMPASS
Exclusive Processes
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CLAS12 DVCS/BH- Beam Asymmetry at 12 GeV
With large acceptance,measure large Q2, xB, tranges simultaneously.
A(Q2,xB,t) (Q2,xB,t)(Q2,xB,t)
ALU
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CLAS12- DVCS/BH- Beam Asymmetry
Luminosity = 720fb-1
Q2=5.5GeV2
xB = 0.35 -t = 0.25 GeV2
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CLAS12 - DVCS/BH Beam Asymmetry
L = 1x1035
T = 2000 hrsΔQ2= 1 GeV2
Δx= 0.05
E = 11 GeV
Selected Kinematics
LU~sinIm{F1H+.}d
epep
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CLAS12- DVCS/BH Longitudinal Target Asymmetry
epep
~sinIm{F1H+(F1+F2)H...}d~
E = 11 GeVL = 2x1035 cm-2s-1
T = 1000 hrsQ2 = 1GeV2
x = 0.05
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CLAS12- DVCS/BH Transverse Target Asymmetry
Asymmetries highly sensitive to the u-quark contributions to theproton spin.
Transverse polarized target
e p ep
~ cosIm{k1(F2H– F1E) +…}d
Q2=2.2 GeV2, xB = 0.25, -t = 0.5GeV2E = 11 GeV
Sample kinematics
AUTx Target polarization in the scattering plane
AUTy Target polarization perpendicular to the scattering plane
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CLAS12– DVCS/BH beam spin asymmetry on neutrons
DVCS on neutrons is sensitive to GPD En and the d-quark content of the nucleon spin.
This program requires adding a Central Neutron Detector (CDN) to the CLAS12 base equipment.
European Initiative led by: Orsay University
CND
CLAS12Forward Detector:- TORUS magnet- Forward SVT tracker- HT Cherenkov Counter- Drift chamber system- LT Cherenkov Counter- Forward ToF System-Preshower calorimeter- E.M. calorimeter
Central Detector:-SOLENOID magnet - Barrel Silicon Tracker- Central Time-of-Flight-Polarized target (NSF)
Proposed upgrades:-Micromegas (CD)- Neutron detector (CD)- RICH detector (FD)- Forward Tagger (FD)
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CLAS12 in construction - examples1. Super Conducting Magnets
– Conductor ready – Torus Coil case being
prepared for coil winding
2. Silicon Vertex Tracker– Testing of the readout chip– Sensor testing
3. Forward Time of Flight– PMT testing at USC– Scintillator testing at USC
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CLAS12 Under Construction - Examples
1. Drift Chambers– Wire stringing of RI at JLab– Wire stringing of RII at ODU
2. High Threshold Cerenkov – Mirror fabrication in the
JLab Clean room – Mirror trimming at JLab
Machine shop
3. Pre-Shower Calorimeter (MRI/NSF)
– Module assembly – Fibers QA
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Two short parasitic installation periods in FY10
6-month installation May-Oct 2011
12-month installation May 2012-May 2013
Hall A commissioning start October 2013
Hall D commissioning start April 2014
Halls B & C commissioning start October 2014
Project Completion June 2015
12 GeV Upgrade Project Schedule
CLAS CollaborationCollaborai
Collaboration
Old Dominion University, Norfolk, VARensselaer Polytechnic Institute, Troy, NY
Rice University, Houston, TXUniversity of Richmond, Richmond, VA
University of Rome Tor Vergata, ItalyUniversity of South Carolina, Columbia, SC
Thomas Jefferson National Accelerator Facility, Newport News, VAUnion College, Schenectady, NY
University Santa Maria, Valparaiso, ChileVirginia Polytechnic Institute, Blacksburg, VA
University of Virginia, Charlottesville, VACollege of William and Mary, Williamsburg, VA
Yerevan Institute of Physics, Yerevan, ArmeniaBrazil, Germany, Morocco and Ukraine,
, have individuals or groups involved with CLAS, but with no formal collaboration at this stage.
Arizona State University, Tempe, AZUniversity Bari, Bari, ItalyUniversity of California, Los Angeles, CACalifornia State University, Dominguez Hills, CACarnegie Mellon University, Pittsburgh, PACatholic University of AmericaCEA-Saclay, Gif-sur-Yvette, FranceChristopher Newport University, Newport News, VAUniversity of Connecticut, Storrs, CTEdinburgh University, Edinburgh, UKUniversity Ferrara, Ferrara, ItalyFlorida International University, Miami, FLFlorida State University, Tallahassee, FLGeorge Washington University, Washington, DCUniversity of Glasgow, Glasgow, UK
Universityof Grenoble, Grenoble, France Idaho State University, Pocatello, IdahoINFN, LaboratoriNazionalidiFrascati, Frascati, ItalyINFN, SezionediGenova, Genova, ItalyInstitut de Physique Nucléaire, Orsay, FranceITEP, Moscow, RussiaJames Madison University, Harrisonburg, VAKyungpook University, Daegu, South KoreaUniversity of Massachusetts, Amherst, MA Moscow State University, Moscow, RussiaUniversity of New Hampshire, Durham, NHNorfolk State University, Norfolk, VAOhio University, Athens, OH
IN2P3 - JLab Meeting
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—The discovery of Generalized Parton Distributions has opened up a new and exciting avenue of hadron physics that needs exploration in dedicated experiments.
— Moderate to high energy, high luminosity, and large acceptance spectrometers are needed to measure GPDs in deeply virtual exclusive processes.
— The JLab 12 GeV Upgrade provides the tools to do this well and explore the nucleon at a much deeper level.
Summary
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CLAS12CLAS12- Institutions
France: - Grenoble University, IN2P3, Grenoble - Orsay University, IN2P3, Paris - CEA Saclay, IRFU, Paris
Armenia: - Yerevan Physics Institute, Yerevan, Armenia
United Kingdom: - Edinburgh University, Edinburgh, Scotland- Glasgow University, Glasgow, Scotland
Russian Federation: - MSU, Skobeltsin Institute for Nuclear Physics, Moscow- MSU, Institute for High Energy Physics, SiLab, Moscow- Institute for Theoretical and Experimental Physics, Moscow
Italy: - INFN - LNF, Roma- INFN - Genova, Genova- INFN - University Bari, Bari- INFN - University Ferrara, Ferrara- INFN - ISS, Roma- INFN - Roma II, Tor Vergata, Roma
Republic of Korea:- Kyungpook National University, Daegu, Korea
United States of America: - Argonne National Laboratory, Argonne, Il- California State University, Dominguez Hills, CA- Catholic University of America, Washington, DC- College of William and Mary, Williamsburg, VA- Christopher Newport University, Newport News, VA- Fairfield University, Fairfield, CT- Florida International University, Miami, FL- Hampton University, Hampton, VA- Idaho State University, Pocatella, ID- James Madison University, Harrisionburg, VA- Norfolk State University, Norfolk, VA- Ohio University, Athens, OH- Old Dominion University, Norfolk, VA- Rensselaer Polytechnic Institute, Troy, NY- Temple University, Philadelphia, PA- Jefferson Lab, Newport News, VA- University of Connecticut, Storrs, CT- University of New Hampshire, Durham, NH- University, of Richmond, Richmond, VA- University of South Carolina, Columbia, SC- University of Virginia, Charlottesville, VA
Chile: - University Santa Maria, Valparaiso
38 Institutions, November 2010