1 Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007 Transition Form Factors at JLab: The Evolution of Baryonic Degrees of Freedom Ralf W. Gothe University of South Carolina Workshop on Partial Wave Analysis and Dalitz Plot Analysis January 25-26, 2007 Beijing, China Introduction N N Roper, and N N* Transitions 1and 2Production
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Transition Form Factors at JLab: The Evolution of Baryonic Degrees of Freedom
Transition Form Factors at JLab: The Evolution of Baryonic Degrees of Freedom. Ralf W. Gothe University of South Carolina Workshop on Partial Wave Analysis and Dalitz Plot Analysis January 25-26, 2007 Beijing, China Introduction N D, N Roper, and N N* Transitions - PowerPoint PPT Presentation
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1Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Transition Form Factors at JLab: The Evolution of Baryonic Degrees of Freedom
Ralf W. GotheUniversity of South Carolina
Workshop on Partial Wave Analysis and Dalitz Plot Analysis January 25-26, 2007
Beijing, China
Introduction N N Roper, and N N* Transitions 1 and 2 Production
2Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Physics Goals
Understand QCD in the full strong coupling regime transition form factors to nucleon excited states
allow us to study relevant degrees-of-freedom wave function and interaction of the constituents
?
!?
! ?
?
!
!Models
Quarks and Gluons as Quasiparticles
ChPT Nucleon and
Mesons
pQCD q, g, qq
< 0.1fm 0.1 – 1.0 fm > 1.0 fm<
3Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Lattice QCD indicates a small oblate deformation of the (1232) and that the pion cloud makes E1+ /M1+ more negative at small Q2.
Data at low Q2 needed to study effects of the pion cloud.
Need data at low Q2
N (1232) Transition Form Factors
4Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
C. Alexandrou et al., PRL, 94, 021601 (2005)
REM (%)
RSM (%)
Quenched LQCD describes REM within error bars, but shows discrepancies with RSM at low Q2 . Pion cloud effects?
Low-Q2 Mutipole Ratios for REM, RSM
Need data at low Q2
5Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Low-Q2 Mutipole Ratios for REM, RSM
C. Alexandrou et al., PRL, 94, 021601 (2005)
preliminary
Quenched LQCD describes REM within error bars, but shows discrepancies with RSM at low Q2 . Pion cloud effects?
Significant discrepancy between CLAS and Bates/MAMI results for RSM.
C. Smith
6Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Data at even lower Q2 are needed to investigate the pion cloud further.
Data at high Q2 are needed to study the transition to pQCD.
Preliminary Multipole Ratios REM, RSM
preliminaryNeed data at
low Q2
7Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Constituent Counting Rule
A1/2 1/Q3
A3/2 1/Q5
GM 1/Q4*
S11 Q3A1/2
F15 Q5A3/2
P11 Q3A1/2
D13 Q5A3/2
F15 Q3A1/2
D13 Q3A1/2
Quark mass extrapolated to the chiral limit, where q is the momentum variable of the tree-level quark propagator using the Asquat action.
Bowman et al. (LQCD)
(GeV
)
8Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
N → Multipole Ratios REM , RSM
New trend towards pQCD behavior does not show up.
CLAS12 can measure REM and RSM up to Q²~12 GeV².
REM +1
M. Ungaro
GM 1/Q4*
9Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
electro-production (UIM, DR)
PDG estimation
, 2 combined analysis
electro-production (UIM, DR)
PDG estimation
, 2 combined analysis
K. Park (Data) I. Aznauryan (UIM)
preliminary
Roper Electro-Coupling Amplitudes A1/2, S1/2
nr |q3
|q3+g
LF |q3
|q3+qq
LF |q3
nr |q3
nr |q3|q3+qq
|q3+g LF |q3
nr |q3
|q3+g
LF |q3|q3+qq
nr |q3
nr |q3|q3+qq
|q3+g
10Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
preliminary
S11(1535) Electro-Coupling Amplitudes A1/2, S1/2
electro-production (UIM, DR)
PDG estimation
S11, D13 combined analysis (SQTM)
K. Park (Data) I. Aznauryan (UIM)
production (UIM, DR)
nr |q3
LF |q3
LF |q3nr |q3
nr |q3LF |q3
LF |q3
nr |q3
11Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Energy-Dependence of+ Multipoles for P11, S11
imaginary partreal part
Q2 = 0 GeV2
The study of some baryon resonances becomes easier at higher Q2.
Q2 = 2.05 GeV2
preliminary
I. Aznauryan (UIM)
12Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Legendre Moments of Structure FunctionsQ2=2.05GeV2
M1- = 0
M1- = 0
I. Aznauryan UIM fit
The dominating final state multipole amplitude M1- of the P11(1440) resonance is at high Q2 are much more prominent than at small Q2.
K. Park
preliminary
CLAS
13Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
invariant mass / MC phase space
BES/BEPC, Phys. Rev. Lett. 97 (2006)
/J p n /J p n BES Bing-Song Zou
and
14Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Fermion Helicity Conservation
Helicity Conservation´ for q M
>>
Quark mass extrapolated to the chiral limit, where q is the momentum variable of the tree-level quark propagator using the Asquat action.
Bowman et al. (LQCD)
(GeV
)
15Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
preliminary
D13(1520) Helicity Asymmetry
Ahel = A1/2
2 – A3/22
A1/22 + A3/2
2
A1/2
A3/2
16Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Nucleon Resonances in 2 Electroproduction
p(e,e’)X
p(e,e’p)
p(e,e’+)n
p(e,e’p+)
2 channel is sensitive to N*’s heavier than 1.4 GeV
Provides complementary information to the 1 channel
Many higher lying N*’s decay preferably to N final states
Q2 < 4.0 GeV2 Trigger
W in GeV
17Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
direct 2production
Full calculationsp-++
p+0
pp
p-P++33(1600)
p+F015(1685)
p+D13(1520)
Combined fit of various single differential cross sections allowed to establish all significant mechanisms
Isobar Model JM05
Contributing Mechanisms to p → p+-
JM05
18Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
CLAS photo-production
W(GeV)
Background
Resonances
Full calculation
no 3/2+
N* contributions are much smaller than non-resonant mechanisms
electro-production
W(GeV)
M. Ripani
3/2+(1720)P?3(1720)
Full JM05 calculation with and without the 3/2+(1720) state
Resonances in p → p+-
19Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Resonances
CLAS
Background
Full JM05
no 3/2+
3/2+(1720)P?3(1720)
Resonances and Background in p → p+
electro-productionphoto-production
JM05
20Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Combined 1-2 Analysis of CLAS Data
PDG at Q2=0
Previous world data
2 analysis
1-2 combined at ////Q2=0.65 GeV2
Many more examples: ////P11(1440),
D13(1520), S31(1650), ////S11(1650),
F15(1685), D13(1700), ////…
EBAC at JLab: ////Full coupled channel analysis
D33(1700) D33(1700)
P13(1720) P13(1720)prelim
inary
JM05
21Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
Combined 1-2 Analysis of CLAS Data
PDG at Q2=0
2 analysis
1-2 combined at Q2=0.65 GeV2
Previous world data
22Ralf W. Gothe Nucleon Transition Form Factors Beijing 2007
vp → 0p
1 Data Description by N* Electro-Couplings of the Combined Analysis