Nucleon Resonances in the Quark Model

About This Presentation

Title:

Nucleon Resonances in the Quark Model

Description:

Partial wave analysis and amplitude analysis give reliable results for dressed ... Undressing dressed scattering matrix singularities in coupled-channel models is ... – PowerPoint PPT presentation

Number of Views:149

Avg rating:3.0/5.0

Slides: 73

Provided by: nstar200

Category:

more less

Transcript and Presenter's Notes

Title: Nucleon Resonances in the Quark Model

1
(No Transcript)
2
NSTAR 2007 Summary

Experiment/analysis
Facilities/new results
Upcoming developments
Theory
Baryons
Dynamics of reactions involving baryons

3
BRAG pre-meeting

L. Tiator, A. Svarc problem relating
experimental results to theoretical predictions
Partial wave analysis and amplitude analysis give
reliable results for dressed scattering matrix
singularities
Quark model calculations give information on bare
resonant quantities
Does not apply to those states seen in chiral
unitary modelssee talks by A. Ramos, E. Oset,
A. Martinez Torres, and M. Doering at this
meeting
Dressing (un-quenching) the quark model is tough,
but solvable in principle
See talks by E. Santopinto, R. Bijker, and B.
Pasquini at this meeting S.C. and M. Giannini in
BRAG pre-meeting
Undressing dressed scattering matrix
singularities in coupled-channel models is in
principle a model-dependent procedure because of
presence of model-dependent hadronic mass shifts
From unmeasurability of off-shell effects
accompanying any dressing procedure.
BRAG pre-meeting talks by Ch. Hanhart, S.
Scherer, J. Gegelia

4
BRAG pre-meeting

Conclusions
(1) Bare quantities in coupled-channel models are
legitimate quantities to be extracted
Only within a framework of a well defined model
To interpret, keep track of the existence of the
hadronic mass shifts produced by
off-shell-ambiguities
(2) Dressed scattering matrix singularities are
best meeting point between quark model
predictions and experiments
Recommendation put a lot of effort into defining
and thoroughly checking the pole extraction
procedures
starting either from energy dependent partial
waves or from partial wave data directly

5
Experimental programs for N

Common developments
Precision data on host of final states
Emphasis on ?N, ?N, 2?N, ??N, K?, K?,
Polarization (beam, target, double planned or
underway)
Aim is to measure as many observables as possible
for a subset of these reactions (complete
experiments)
Reduce (not eliminate) model dependence of
analysis
Challenge for models to fit polarization
observables
Strong sensitivity to resonance properties
This is how physics progresses!

6
CLAS_at_Jefferson Lab
Expt.

V. Burkert CLAS collaboration
Major focus is N physics
the search for new baryon states and
determination of baryon resonance properties
resonance transition form factors
Nucleon spin structure in the transition region
polarized proton structure function g1(x,Q2)
Bjorken Sum ?1p-n(Q2)
Deeply exclusive processes and generalized parton
distributions (GPDs)
DVCS/Bethe-Heitler beam spin asymmetry sensitive
to H

7
CLAS_at_Jefferson Lab
Expt.

Search for new baryon states
Aim for complete or nearly complete
measurements
?p?pN, ?N, KY and ?n?pN, K0Y
Combinations of beam, target (new FROST target),
and recoil polarizations
differential cross sections with unpolarized,
circularly polarized, and linearly polarized
photon beams
recoil polarizations for hyperons
longitudinally or transversely polarized proton
and neutron (deuteron) targets
Other reactions
?p ? ?N, ?p, ppN
linearly polarized beams, polarized beam and
polarized targets

8
CLAS_at_Jefferson Lab
Expt.

R. Schumacher polarization transfer in K?
photo and electro-production
Polarized beam, ? (recoil) polarization through
its weak decay asymmetry
New GRAAL results for recoil polarization P agree
with CLAS results
Large polarization transfer Cz along circularly
polarized photon beam direction
Find P2 Cx2 Cz2 ' 1
Models did not predict this
Bonn, Giessen, Gatchina (Sarantsev, Nikonov,
Anisovich, Klempt, Thoma ) fit with additional
resonance P13(1860)
See talks by A. Sarantsev, V. Nikonov this
meeting
Beam asymmetry ? featureless (GRAAL, LEPS)

9
CLAS_at_Jefferson Lab
Expt.
10
CLAS_at_Jefferson Lab
Expt.
11
CLAS_at_Jefferson Lab
Expt.

V. Burkert, V. Mokeev
Q2 dependence of EM transition form factors (0-6
GeV2) using CLAS_at_Jefferson Lab
Probes evolution of relevant degrees of freedom
in baryons
e-N ! ? ! N?
Dominant M1 contains non-resonant effects
involving ?, at level of 30
Ratios of electric and scalar (quadrupole)
multipoles to M1 measured to 0.5-2 over entire
range of Q2
Do not tend to pQCD limits
e-N ! N½(1440) ! N?, N??
Changes sign at Q2 0.5 GeV2 (seen in
relativistic models based on light-cone dynamics)
Consistent results using different analysis
methods, different final states

12
Electron scattering labs
Expt.
Np, ppp-
np
DR
UIM
pp0
np
pp0

CLAS_at_Jefferson Lab

13
Electron scattering labs
Expt.
D13(1520)
P11(1440)
from analysis of 1p CLAS data
from analysis of CLAS 2p data within the
framework of JM06
combined analysis of 1p/2p CLAS data
14
Electron scattering labs
Expt.

N3/2-(1520)D13

A3/2
Previous pp0 based data
preliminary
preliminary
A1/2
Q2, GeV2
Q2, GeV2
15
CLAS_at_Jefferson Lab
Expt.

Cascade (?0 ssu, ?- ssd) baryon program
Advantage that low-lying states are likely narrow
?p?gtKK?-
?p?gtp-KK?0

16
BaBar
Expt.

Veronique Ziegler ee- annihilation at BaBar
(results preliminary, under BaBar internal
review)
Study ?0(1530) in ?c ! (?-?) K
Indication is J3/2 (confirms decuplet
expectation)
Study ?0(1690) in ?c ! (LK 0) K
Preferred spin is J1/2, some indication of
negative parity
If negative parity, not Roper equivalent as some
of us (!) thought
Much too light for quark model expectations of
L1 excited states N 2(ms-mu,d) !
Calculable on the lattice (D. Richards)

17
Crystal Barrel/TAPS_at_ELSA
Expt.

H. Schmieden Physics at ELSA
Photoproduction of baryon resonances
ELSA
photon beam energy (to 2.5 GeV)
Linear and circular polarization
CB/TAPS
provides 4? detection
Best for neutral final states (missing mass for
a charged particle) through their photon decays

18
Crystal Barrel/TAPS_at_ELSA
Expt.

Goal complete experiments on ? and ?
photoproduction
Analysis simplified because only make N (no D)
Recent results
Unpolarized photoproduction of ?
Differential cross sections
From ?? and 3?0! 6? decays of ?
Linearly polarized photoproduction of ? (D.
Elsner talk)

19
Crystal Barrel/TAPS_at_ELSA
Expt.

D. Elsner linearly polarized photoproduction of
?
Targetpolarization ?
Consistent withGRAAL results

20
Crystal Barrel/TAPS_at_ELSA
Expt.

Photoproduction of ? off deuteron

21
Crystal Barrel/TAPS_at_ELSA
Expt.

Data analysed to d?/d?
Bonn-Gatchina PWA
see P11(1840)
Polarization asymmetries R, ?

22
Crystal Barrel/TAPS_at_ELSA
Expt.

Talk by E. Gutz polarization asymmetry ? in
Bonn-Gatchina PWA ?(1940)D33

23
Crystal Barrel/TAPS_at_ELSA
Expt.

Polarized photoproduction of ?
Penner et al. and Shkylar (Giessen) analyses
disagree

24
ANKE, TOF_at_COSY
Expt.

W. Schroeder
ANKE can see Y states up to 1540 MeV, TOF is
best for threshold region
pp! pKY0! pK? X
Select events where X- ?-, plot vs. MM(pK)
Effect in X-?at 1480 MeV,?60 MeV
Also in X?-

25
ANKE, TOF_at_COSY
Expt.

ANKE line shape of ?(1405)
Not Breit-Wigner, see talk by E. Oset this meeting

L.S. Geng, E. Oset, arXiv 0707.3343
26
ANKE, TOF_at_COSY
Expt.

TOF
See no ? pentaquark in pp! (pK0)? or in
(pK0)??
Need polarized beam, target and detector
improvements to continue program of examining N!
YK in 1.6-1.9 GeV region
New detector WASA (? and neutrals) will allow
study of excited hyperons
pp! pK?(1405)! pK?0?0! pK(??)?0

27
Crystal Ball/TAPS_at_MAMI
Expt.

M. Kotulla
Determination of magnetic moment of ?(1232)
Use ? p! ?0 ?0 p

28
Crystal Ball/TAPS_at_MAMI
Expt.

Analysis effort underway
Pascalutsa and Vanderhaeghen, chiral effective
theory (good to E? 100 MeV)
Sensitivity 0.2 ?N

29
BESII_at_IHEP
Expt.

W. Li light hadron spectroscopy in J/? decays
New states
?, ? (masses and widths determined)
X(1835) in J/?? ??????
X(1580) in J/?? KK?
Enhancement in J/?? ???
?(1760) in J/?? ???
N observed in
J/?? pn?? J/?? pp?0 J/?? nKS? Compared with
?(2S) decay
Some N, e.g. N(1535), N(2065) better measured
Some branching fractions involving baryons are
measured
Analysis of existing data ongoing
BEPCII/BESIII should collect data in 2008

30
LNS_at_Sendai
Expt.

H. Shimizu observation of N(1670)
Have 300 MeV e- linac coupled to a 1 GeV
synchroton
Use ?d ! ?X
Also ?p ! ?X to subtract proton contribution
Use ?-MAID analysis to understand ?p ! ?p
Interpret as new S11 at 1670 MeV, width below 50
MeV, strong in ?n ! ?n
Not seen in proton channel
Could this be an antidecuplet pentaquark?

31
LEGS_at_BNL
Expt.

A. Sandorfi Physics at LEGS
LEGS-Spin collaboration
LEGS 2.8 GeV e- beam, backscattered laser beam,
maximum photon energy 430 MeV
High circular polarization
HD frozen spin
Hydrogen polarized or D polarized or both
Mostly HD and a little H2 and D2 which feed HD
polarized state (then decay away themselves, so
HD spin frozen)
Spin relaxation times 1 year
Can transfer polarization from H to D
Polarized photon HD double-polarization physics
Measure various polarization asymmetries in
inclusive and exclusive ? HD ! ? X reactions on
neutron
Use Lee Sato Matsuyama ? N! ? N amplitudes and
fold into D structure

32
LEGS_at_BNL
Expt.

Analysis
Not a free neutron! Only half of the events are
quasi-free
Analysis of data on-going separate ? using
momentum analysis
Targets and some of staff migrating from BNL to
JLab
E06-101 ?(pol) HD ! K0?(pol), K0?(pol), i.e. ?n
Electron experiments on transversely polarized
target
GPDs, N form factors, Collins/Sivers functions

33
MAMI_at_Mainz
Expt.

A. Thomas Physics at MAMI
Virtual and real photons, linear and circular
polarization
Three detectors Kaos,,Crystal Ball/TAPS
MAMI
Harmonic double-sided microtron (electron
accelerator)
four bending magnets and two linacs
Energy 0.855-1.5 GeV
Tagged photon and electron scattering experiments
Experiments
Target asymmetry puzzle in ? and ?0 production
off proton
Isobar models and Giessen models fail to describe
Electroproduction of ? at low Q2
Cross section and recoil polarization
Single and double pion production
Helicity asymmetry in double-pion production
Discrepancies with models

34
MAMI_at_Mainz
Expt.

Physics at MAMI
?, ?0 physics
? mass, rare ? decays (C,CP violation)
Quark mass different mu-md in ? ! 3?0
?0 ! ??0?0 decays
GDH experiment _at_ MAMI-B with DAPHNE detector
(charged particle tracking)
Polarized butanol target with high deuteron
polarization
MAMI/ELSA GDH sum rule ?3/2-?1/2
Verified at 10 level
Also in exclusive reactions, important for PWAs
Have for ? production
Photoproduction of p??-
Helicity-dependent invariant mass distributions
The future
Frozen spin target for Crystal Ballbuilt this
year
Recoil polarization of proton
Kaoskaon electroproduction

35
Theory developments

Both lattice QCD and quark model calculations
must face reality of light quark pairs
Un-quenching either is hard work
Requires calculation of couplings to continuum
states
Coupled-channel analyses are becoming
increasingly sophisticated
Need to preserve unitarity, gauge invariance, and
analytic structure, but remain manageable

36
Lattice QCD
Theory

The nucleon and baryon resonances on the lattice
C. Gattringer (Graz-Regensburg), D. Richards
(LHPC collaboration), A. Rusetsky
Recent important developments
Basic quantities are Euclidean two and
three-point functions
Time dependence of two-point functions gives
masses
Matrix elements in three-point functions give
properties
Extraction of excited state masses using
carefully chosen basis of interpolators Oi
Use these to construct a matrix of correlators
Solve eigenvalue problem to get accurate signal
for mass of excited states

37
Lattice QCD
Theory

Eigenvalues ??(t) vs. Euclidean time

38
Lattice QCD
Theory

Recent important developments
Hadron interpolators distributed over spatial
lattice points
LHPC collaboration, Graz-Regensburg
classify into irreducible representations of
lattice rotation group
Allows nodes in radial wave function
Can avoid chiral extrapolations by using chiral
perturbation theory in a finite volume
(small-scale expansion) See talk by A. Rusetsky,
this meeting
Luscher formalism developed for ?N scattering
Use statistical method to extract resonance mass
and width from lattice results
Demonstrated for ?(1232) mass and width

39
Lattice QCD
Theory

Spatially distributed interpolators
Much better overlap with excited states

40
Lattice QCD
Theory

Baryon spectrum, quenched calculations

41
Lattice QCD
Theory
42
Lattice QCD
Theory

Proton structure from three-point functions,
chiral extrapolation to physical pion masses
Different treatment of valence and sea quarks
allows first look at chiral regime (un-quenched)
Isovector charge form factor (p-n)
Isovector charge radius
Axial charge gA
Moments of quark momentum fraction hxiu-d and
helicity fraction hxi?u -?d
Study of GPDs
Calculation of quark orbital angular momentum
Nucleon transverse size

43
Lattice QCD
Theory

Lu and Ld substantial, total small

44
Lattice QCD
Theory

Un-quenched calculations in development
Need clean separation of scattering states once
decays possible
Use different volume dependence of masses of
resonances and continuum states, large lattices
Working on evaluating transition matrix elements
(decay constants) for resonances
Need contribution of disconnected diagrams
(loops, gluons) to hadron structure
Currently sensitive to statistical fluctuations

45
Models
Theory

B. Borasoy chiral corrections to the Roper
resonance mass
Lighter than its parity partner S11(1535)
30-40 branch into N??
Parity order not settled in lattice QCD
Need reliable chiral extrapolation techniques
Use effective Lagrangian (N, Roper, ?), calculate
mR(m?2) to full 1-loop order (no explicit ?p)
Have R? coupling gA ' 1.26, RN? coupling
(0.3-0.4), 4 chiral parameters
Infrared regularization scheme extended to one
light scale (m?) and two heavy (MN2 ltlt MR2)
No strong m? dependence near physical point

46
Models
Theory

Constituent Quark Model E. Santopinto, R.
Bijker
See also talk by Qiang Zhao, this meeting, on
selection rules and quark correlations in the N
spectrum
See also talk by A. Buchmann, this meeting, on
calculation of higher (octupole) moments of
baryons in pion-cloud quark model
Tackle difficult problem of inclusion of next
Fock space component in quark model
Use large baryon-meson basis to expand qqq
qq(bar)
Flux-tube breaking model gives overlap between
qqq and qqq qq(bar)
Checked that calculation returns usual CQM in
closure limit
Evaluate flavor asymmetry of nucleon sea

47
Models
Theory

Results significant difference from naïve
nonrelativistic CQM results and relativistic CQM
results
Closer to experiment and lattice QCD

?u 1.00 ?uexp 0.82(5) ?uLQCD
0.79(11) ?uNRM 4/3 ?uRQM 1.01 ?d
-0.43 ?dexp -0.44(5) ?dLQCD -0.42(11)
?dNRM -1/3 ?dRQM -0.251 ?s -0.06
?sexp -0.10(5) ?sLQCD -0.12(11) ?sNRM
0 ?sRQM 0

48
Models
Theory

B. Metsch Covariant constituent quark model
Based on instantaneous approximation to
Bether-Salpeter equation
Relativistic form of confining potential, chosen
to minimize spin-orbit effects
Instanton-based spin-spin interaction between
quarks
Model parameters fit to spectrum
Calculate a host of other properties
Magnetic moments and charge radii
Including magnetic moments of excited states
Resonance photocouplings and semi-leptonic decays
Strong two-body decay amplitudes
Verifies pattern of decoupling of states not seen
in analyses

49
Models
Theory

B. Metsch Covariant constituent quark model
Provides useful background against which to
search for unconventional states
Roper resonance EM couplings anomalous
Everything (mass, EM and strong couplings) about
the ?(1405) is anomalous
Hard to understand why the second band of
negative parity ? states D35 and its partners
can be as low as 1900 MeV

50
Models
Theory

Chiral Unitary Approach A. Ramos, E. Oset
KN I0 JP1/2- (S01) scattering state ?(1405) is
27 MeV below threshold
Looks like quasi-bound state
Use chiral meson-baryon Lagrangian to generate an
S-wave potential
Need KN, ??, ??, and K? channels to fit decay
branching ratios of this and nearby states
Get two poles in T matrix approaching 1400 MeV
when break SU(3)f gradually
Explains why properties of ?(1405) depend on
channel in which it is observed

51
Models
Theory

?(1405) in chiral unitary approach pole
positions move as break SU(3)f gradually

52
Models
Theory

?-p! K0??N mass 1385 ? 50 MeV
K-p! ?0?0?0 mass 1420 ? 38 MeV
Other baryons in the chiral unitary approach
JP1/2- N(1535), ?(1620), ?(1690)
JP3/2- ?(1700), ?(1520), ?(1670), ?(1820)
From baryon decuplet interacting with meson 0-
octet
?(1620) bump seen at Jefferson Lab in ?p!
?-KK-(??)
Width is larger than width of ?? invariant mass
distribution (near threshold)
No claim for this state made in JLab
experimental paperV. Burkert

53
Models
Theory

Chiral Unitary Approaches A. Ramos
Heavy flavored baryons udc ?c(2593)
DN s-wave molecule
Predicts another ?c(2800), similar to
experimental state
Interaction of charmed mesons in hadronic medium
DD-
Important for explaining J/? suppression in
heavy-ion collisions
Related to nucleon-antinucleon interactions

54
Models
Theory

Chiral Unitary Approaches E. Oset
?(1405) is an interesting state
See two poles in many models, one couples
strongly to ??, the other to KN
Experimental tests of ?(1405) structure
K-p ! ??(1405)
K-p ! ?0?(1405)
Radiative decay of two ?(1405) states
Different shapes and rates for two states
depending on reaction used
K-p! ?0??, ?0??0
pp ! Kp?(1405) measured by ANKE_at_COSY
Fit with kaon, pion and rho exchange diagrams

55
Models
Theory

Excited baryons in 1/Nc expansion C. Schat
How do we match quark models to 1/N_c?
Useful perturbative expansion
Baryons fall into irreducible representations in
large N_c limit
N_c counting rules
Quark operator expansion Hmass? ciOi and fit
constants to baryon masses
Detailed calculations for L1 baryons
To leading order write down all operators with
correct properties
Have explicit flavor dependence (different from
OGE)
Fit to 5 N1 excited states degenerate S11/D13
D13/D15 pairs in large Nc limit
Orderings of singlet and two doublets not
specified by 1/Nc

56
Models
Theory

Excited baryons in 1/Nc expansion
Extend using 1/Nc corrections and SU(3)f
?(1405) and ?(1520) split by spin-orbit operator
What order is spin-orbit interaction?
Is core - exited quark separation necessary?
How match to quark model?
Consider
One gluon exchange (general spatial dependence)
OPE (now explicit flavor dependence)

57
Models
Theory

Shows using exchange symmetry that can calculate
orbitally excited states using CCGL states
Expression for most general OGE and OPE mass
operators (different)
Constants written to leading order in overlap
integrals
Match forms to general form in 1/Nc
OGE has c30 but fits in literature show not zero
Conclusion
SN analysis shows core and excited core basis
necessary
Matching to quark models reproduces 1/Nc operator
expansion
Spin orbit is leading order, partial cancellation
between LS coming from OGE and OPE flavor
dependent interactions
Matching method very general

58
SAID/MAID analyses
Expt.

B. Briscoe, George Washington University Data
Analysis Center (SAID) L. Tiator, S. Kamalov
Mainz (MAID)
Maintain important database for most reactions
including N
On-line analysis tools important for single and
coupled-channel analysis of data
New analysis of ?N! ?N, photo and
electro-production of p0n, ?p by GWDAC
4-channel K-matrix ?N, ?N, ??, ?N up to 2.5 GeV
CLAS, CB-ELSA and GRAAL data
A1/2 from Np analysis for S11(1535) now agrees
with N? results
Agrees with previous result from
electro-production
P13(1720) has large Ap1/2
consistent with earlier analysis of ppp- in low
Q2 electro-couplings

59
Coupled-channel analysis
Theory

A. Sibirtsev Resonances in hadron-induced
interactions
See also talk by S. Krewald, this meeting, for a
description of the Juelich coupled-channels
approach to resonance analysis
Need to match to Regge theory (pQCD) at very high
energy
Matches down to 3 GeV, PWA stops at 2.4 GeV
Evidence of resonances in 2.43 GeV region?
Through optical theorem find forward-pion
charge-exchange indicates structures up to 3 or 4
GeV
Also ?-p! ?0n data show traces of high-mass
baryons
Dont neglect single-pion photoproduction for
high mass Ns (dont stop calculating in models
at 2 GeV)

60
Coupled-channel analysis
Theory

Giessen V. Shklyar (G. Penner, U. Mosel, H.
Lenske)
Data on
Unitarity optical theorem relates forward part
of elastic scattering T matrix to inelastic c.s.
to various channels (NEXT SLIDE)
NOT UNRELATED!
Solve D-S eqn in ladder approximation
V has s, u and t-channel diagrams (matrix in
channel space)
Use effective Lagrangian approach (relativistic)
Solve Bethe-Salpeter equation by putting
intermediate particles on mass shell
Allows PW decomposition, equations become
algebraic
Compare to SAID analysis PWs
Works well for ?N but misses some PWs in ?N
Focus on ?p! ?p (and on neutron)

61
?N, ?N total cross sections
62
Coupled-channel analysis
Theory

?p! ?p (and on neutron)
S11(1535) properties not well known, complicates
analysis in this region
Ratio of helicity amplitudes in ?N! ?N differs
from ! ?N
Fit GRAAL beam asymmetry ? data well, target
asymmetry not so well
Fit d?/d? for ?p ! ?p well, with S11(1650) giving
structure at 1670 MeV
No need for new resonance in ?N
Destructive interference effect in ?-N! ?N from
S11(1650) and P11(1710) at higher mass explains
bump

63
Coupled-channel analysis
Theory

Giessen V. Shklyar
Narrow bump in differential c.s. ?n at 1670, is
this a new state?
GRAAL also see this bump (see talk by V.
Kuznetzov)
Non-strange partner of ? ?
Exotic state?
Could S11(1650) and P11(1710) explain this effect
at 1670 MeV?
Look at all reactions simultaneously to make sure
have treated these resonances properly
Can fit with existing resonances, what price do
you pay?
Need larger neutron photocoupling for S11
S11(1650) properties agree with PDG P11(1710) is
not as well known as implies!
Change slightly size of 1650 An1/2, up comes bump
in ? for ?n! ?n SHOW GRAPH
Shape of differential c.s. not changed
Cannot rule out narrow P11(1675), data not yet
good enough
Be careful about Fermi motion in neutron state
Beam asymmetry ? may help

64
Coupled-channel analysis
Theory

MAID analysis S. Kamalov (D. Drechsel, L.
Tiator, S.N. Yang)
MAID 2007, recent results for pion photo and
electroproduction
Two-step process
Extract partial waves
Model dependence because of lack of data
Extract resonance parameters from partial waves
Background and resonance T matrices
Background contains pion loop SHOW DIAGRAMS
defined by K-matrix theory from background
T-matrix
Resonances dressed by pi N rescattering
Phase put into resonance piece to allow unitarity
(Watsons theorem)

65
Coupled-channel analysis
Theory

MAID analysis S. Kamalov
Pion/photoproduction data set now includes
GWU/SAID, Mainz, Bonn, GRAAL, LEGS
Results
S11(1535) photocouplings differ from SAID by a
factor of 2, smaller than PDG
P13(1720) shows up here, not in SAID
See bump in P11 partial wave
Fit an additional P11 at 1700 MeV, ?30 MeV
Electroproduction
Better data has improved situation

66
Coupled-channel analysis
Theory

MAID analysis S. Kamalov
? electroproduction
A. Buchmann has parameterized E/M, S/M, and MAID
fit to this form
RSM(Q2) related to neutron EM form factors
Quite different S1/M1 than CLAS analysis
Q2 dependence of A1/2 and A3/2 for first
resonances in P11, S11, D13, and F15
Helicity asymmetry changes sign in case of F15
also

67
Coupled-channel analysis
Theory

Bonn/Gatchina analysis A. Sarantsev
Need polarization to sort out photoproduction
Technique
Relativistically invariant
Simultaneously analysis single and multiple-meson
production
Specify energy dependence due to unitarity and
analyticity
Unitarize using K-matrix approach, has poles for
resonances
Doesnt use real part of loops (real part smooth
in physical region.)
Use dispersion relations to put in below
threshold (but not everywhere)
Regge-ized t- and u-channel exchange amplitudes
for background
Use maximum likelihood method for three-particle
final states N?? and N??
s-channel a product of two isobar terms

68
Coupled-channel analysis
Theory

Bonn/Gatchina analysis results
Need ?-p! n?0?0 at higher energy, fit well ? p!
p?0?0
Find helicity 1/2 and 3/2 amplitudes
Help to establish properties of existing states
S11(1650) Ap1/2 significantly larger than PDG
D13(1520) lower photocouplings than PDG and agree
with SAID 07
Roper has largest coupling to ? N
A1/2 has phase of residue of almost 90deg, sign
different than PDG
Eta photoproduction data from GRAAL stops at 1933
MEVclaim of new state N(2070)D15 requires double
polarization data
K? CLAS/CB-ELSA (see Nikonov talk)
need P11(1860) and P13(1900)
Fit to pi0 eta photoproduction total c.s. (Horn
et al)
Need second D33(1940) at high energy
Need polarization data

69
Analysis
Theory/Expt

Matt Bellis CMU analysis technique
Event-based energy independent amplitude analysis
Describe the events in a small energy bin with
some set of processes
Take out acceptance, get d\sigma/d\Omega
Get resonance terms, NR term, phase difference
between resonant terms
Use Rarita-Schwinger formalism (used by
Bonn-Gatchina group)
Dont need energy dependence in s-channel
propagator since bin in W
Need to put in t and u-dependence into
non-resonant terms
Find minimum set of diagrams which preserves
gauge invariance and describes data
See set of channels included (high statistics
data sets) from CLAS
Show ?K, p? results, unpolarized photon beam