What is a resonance? What is a resonance? - a peak in the cross section ? - a peak in the imaginary part of a pw amplitude associated with a zero in the real part ? - a pole of the T-matrix in the 2nd Riemann sheet ! e.g. with a maximum in the speed-plots of pw amplitudes resonance part determines the pole background can be neglected
Baryon Resonance Analysis from MAID D. Drechsel, S. Kamalov, L.
Tiator What is a resonance? What is a resonance? - a peak in the
cross section ? - a peak in the imaginary part of a pw amplitude
associated with a zero in the real part ? - a pole of the T-matrix
in the 2nd Riemann sheet ! e.g. with a maximum in the speed-plots
of pw amplitudes resonance part determines the pole background can
be neglected possible requirements for an ansatz or a model of pion
photoproduction gauge invariant covariant or at least relativistic
crossing symmetric chirally symmetric fulfill low-energy theorems
analytic unitary fulfill dispersion relations MAID Ansatz effective
Lagrangian with fields on tree-level isobar model for N* and
resonances (only with 4-stars) background partial waves are
unitarized with K-matrix method for all S, P, D and F waves, higher
background partial waves are taken from real Born terms P 33
(1232), P 11 (1440), S 11 (1535), S 11 (1650), S 31 (1620) are
unitarized up to the region, above we fit a constant phase other
resonances: D 13, D 33, D 15, P 13, P 31, F 15, F 35, F 37, we dont
unitarize, but fit a constant phase as above MAID unitarization
procedure K-matrix unitarization for all background partial waves
up to L=3 MAID unitarization procedure a correction phase (W) for
all Breit-Wigner resonance contributions the energy dependent width
implicitly includes the coupling to other channels Definition of
the electromagnetic NN* Couplings (e.g. Arndt et al, 1990 or PDG)
reduced multipoles: therefore, we need a Partial Wave Analysis with
resonance and background separation for helicity amplitudes and
transition form factors we need the imaginary parts of the
resonance multipoles Definition of the N-N* Form Factors helicity
amplitudes: reduced multipoles from PWA: Sachs form factors:
covariant (Dirac) form factors: for spin resonances as Roper P 11
or S 11 we get only 2 ff different sets of form factors can be
defined as linear combinations of the reduced multipoles Delta: P
33 (1232) Roper: P 11 (1440) N*S 11 (1535) N*D 13 (1520) N*S 11
(1650) N*D 15 (1675) N*F 15 (1680) N*P 13 (1720) with MAID we have
performed a detailed analysis of Transition Form Factors for the
following Baryon Resonances data base for pion electroproduction
data in the region up to W = 1.3 GeV data up to the 3rd resonance
region up to W = 1.7 GeV JLab/Hall CFrolov1999 p0p0 Q = GeV
BatesMertz et al.2001 p0p0 Q = GeV MainzPospischil et al.2001 p0p0
Q = GeV BonnBantes, Gothe2002 p0p0 Q = 0.6 GeV MainzElsner et al. /
Stave et al.2006 p0p0 Q = GeV JLab/Hall AKelly et al.2007 n0n0 Q =
1.0 GeV JLab/CLASVillano et al.2008 prelim. p0p0 Q = 6.0 7.9 GeV
JLab/CLASJoo et al.2002 / 2003 p0p0 Q = 0.4 1.8 GeV JLab/CLASJoo et
al.2004 n+n+ Q = GeV JLab/Hall ALaveissiere et al.2004 n0n0 Q = 1.0
GeV JLab/CLASEgiyan et al.2006 n+n+ Q = 0.3 0.6 GeV JLab/CLASUngaro
et al.2006 p0p0 Q = 3.0 6.0 GeV JLab/CLASPark et al.2008 n+n+ Q =
1.7 4.5 GeV E/M and S/M ratios for the N transition the analyses
are based on 0 data from JLab, Mainz, Bonn and Bates analysis fit A
fit B Ji, Ma, Yuan, PRL 90, 2003 pQCD with angular momentum effects
Nucleon -> Delta on the Lattice C. Alexandrou et al., 2008
dynamical fermions m down to 360 MeV G M : main problems at small Q
(pion cloud) R EM, R SM : in agreement within large uncertainties
transition form factors of the Roper comparison of MAID and JLab
analysis A 1/2 S 1/2 MAID analysis 2007/08 JLab analysis 2008 F2F2
F1F1 Huey-Wen Lin (JLab), ECT*, Trento 2008 Nucleon-Roper
Transition Form Factors on the Lattice again problem with pion
cloud at small Q Transverse Densities (Miller 2007 and Carlson,
Vanderhaeghen 2007) for unpolarized nucleons or resonances: for
polarized nucleons or resonances: the Breit frame, mostly used in
nuclear physics, is not a propriate frame for the nucleon or
nucleon resonances e.g. Z- graphs spoil the density interpretation
these problems do not exist in the infinite momentum frame (on the
Light Cone), where q + =0, and Z- graphs are suppressed in this
frame transverse densities can be defined as 2-dim. Fourier
transforms of the Dirac form factors Transverse Charge Densities of
the Nucleon and N -> Roper (in collaboration with Marc
Vanderhaeghen, Phys. Lett. B 672 (2009) 344) N S 11 (1535) MAID
analysis 2007/2008 JLab analysis 2008 longitudinal: S 1/2
transverse: A 1/2 N D 13 (1520) A 3/2 A 1/2 longitudinal: S 1/2
MAID analysis 2007/2008 JLab analysis 2008 Transverse Charge
Densities of the Nucleon and N -> Roper (in collaboration with
Marc Vanderhaeghen, in preparation) N F 15 (1680) resonances with
some forbidden amplitudes forbidden resonances with some forbidden
amplitudes Summary and Conclusions MAID: set of single-channel
partial wave analysis programs on the basis of isobar models recent
results from channel (Maid2007/08): N->N* transition form
factors for 13 N*/ resonances with **** PDG rating reasonably well
for: I=3/2: P 33 (1232) I=1/2 proton: P 11 (1440), S 11 (1535), D
13 (1520), F 15 (1680) S 11 (1650), D 15 (1675), P 13 (1720),
