Jefferson Lab and SINP MSU, on behalf of the CLAS Collaboration

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Jefferson Lab and SINP MSU, on behalf of the CLAS Collaboration Nucleon Resonance Structure from the CLAS@JLAB Meson Electroproduction Data V.I. Mokeev, Jefferson Lab and SINP MSU, on behalf of the CLAS Collaboration 16th Lomonosov Conference on Elementary Particle Physics

n l±,0 l±,0 n Weak and Electromagnetic Interactions as the Tools for Exploration of the Ground and Excited Nucleon State Structure Weak interaction: neutrino-nucleon scattering: n l±,0 l±,0 n W, Z W, Z N N X N Electromagnetic interaction: electron (muon)-nucleon scattering: e-’ e-’ e-’ e- e- e- gv gv gv S N* N N N X

N*-States in Inclusive Electron Scattering Total virtual photon cross sections F. Foster and G.Hughes, Rep. Progr. Phys. 46, 1445 (1983). The peak content Q2, GeV2 1000 P33(1232) P11(1440), D13(1520), S11(1535)., S31(1620) What we knew 30 years ago: 0.1 100 0.5 S11(1650), F15(1685), D33(1700), P11(1710), P13(1720). 3/2+(1720). 1.3 three resonant peaks. different Q2-evolution of these peaks different structure of different N*-states. s, mcbn 2.3 3.3 5.0 10 6.0 1.2 1.5 2.0 W, GeV

Extraction of gvNN* Electrocouplings from the Data on Exclusive Meson Electroproduction off Protons Resonant amplitudes Non-resonant amplitudes e’ p, h, pp,.. p, h, pp,.. γv e * N*,△ + N N’ N’ N A1/2(Q2), A3/2(Q2), S1/2(Q2) or G1(Q2), G2(Q2), G3(Q2) GM(Q2), GE(Q2), GC(Q2) See details in: I.G.Aznauryan and V.D.Burkert, Progr. Part. Nucl. Phys. 67, 1 (2012). Separation of resonant/non-resonant contributions within the framework of reaction models; Breit-Wigner ansatz for parameterization of resonant amplitudes; fit of resonance electrocouplings and hadronic parameters to the data. Consistent results on gvNN* electrocouplings from different meson electroproduction channels and different analysis approaches demonstrate reliable extraction of N* parameters.

CEBAF Large Acceptance Spectrometer Torus magnet 6 superconducting coils Large angle calorimeters Lead/scintillator, 512 PMTs Liquid D2 (H2)target + g start counter; e minitorus Gas Cherenkov counters e/p separation, 216 PMTs Drift chambers argon/CO2 gas, 35,000 cells Time-of-flight counters plastic scintillators, 684 PMTs Electromagnetic calorimeters Lead/scintillator, 1296 PMTs The unique combination of the CEBAF continuous electron beam with the best worldwide parameters and the CLAS detector of nearly 4p acceptance makes Hall-B@JLAB the most versatile facility operational worldwide for exploration of the nucleon structure. V.I.Mokeev, NSTAR 2013 Workshop Peniscola, Spain, May 27-30, 2013

Motivation and Objectives for the Studies of the gvpN Motivation and Objectives for the Studies of the gvpN*-Electrocouplings in Exclusive Meson Electroproduction The CLAS experimental program seeks to determine gvpN* electrocouplings at photon virtualities up to 5.0 GeV2 for most of the excited proton states through analyzing major meson electro-production channels independently and in global multi- channel analyses. This information is needed to study the evolution of relevant degrees of freedom in N* structure with distance and to access the non-perturbative strong interaction which generates N* states as bound systems of quarks and gluons: I. G. Aznauryuan et al., Int. J. Mod. Phys. E22, 133015 (2013). The non-perturbative strong interaction represents the most important part of the Standard Model that we have yet to explore.

Non-Perturbatively Generated Effective Degrees of Freedom in the Ground and Excited Nucleon State Structure Emergence of dressed constituent quarks (C.Q.) and gluons: dressed quark bare quark dressing kernel dressed gluon bare gluon dressing kernel Dressed quarks and gluons acquire dynamical, momentum dependent structure and masses in the regime of large as which is relevant for the N* formation. Their non-perturbative interactions are very complex and far beyond the scope of pQCD.

quark/gluon confinement Resonance Electrocouplings as a Window into Non-perturbative Strong Interaction quark/gluon confinement The N/N* generation: C.Q. C.Q. C.Q. Exploration of the N/N* state structure addresses the most fundamental questions: Nature of >98 % of the hadron mass in Universe, which is generated non-perturbatively . The Higgs mechanism is almost irrelevant for the light hadron mass generation. How quark-gluon confinement in baryons emerges from the QCD. Available/future data on elastic form factors and gvpN*-electrocouplings from CLAS/CLAS12 detectors offer the access to the dressed quark mass function in the range of momenta p up to 1.15 GeV.

1.30<W<1.56 GeV; 0.2<Q2<0.6 GeV2 The CLAS Data on p+p-p Differential Cross Sections and their Description within the Framework of Meson-Baryon Reaction Model JM G.V.Fedotov et al, PRC 79 (2009), 015204 1.30<W<1.56 GeV; 0.2<Q2<0.6 GeV2 M.Ripani, V.I,Mokeev et al, PRL 91 (2003), 0220021.40<W<2.30 GeV; 0.5<Q2<1.5 GeV2 full JM calc. p+D0 rp p+F015(1680) p-D++ 2p direct p+D013(1520)

The JM Model for Analysis of the p+p-p Electroproduction Major objectives: extraction of gvNN* electrocouplings and the pD, rp decay widths. g p- g p-/+ D++/0 (1232)P33, N0 (1520)D13, D++ (1600)P33, N0(1680)F15 p+ = p p p p’ six meson-baryon channels and direct p+p-p production. N* contribute to pD and rp channels only. unitarized Breit-Wigner ansatz for resonant amplitudes. p’ g p- p-, p+, … g r p+ p+, p-, … + + Last diagram 1&2) meson meson 3) meson baryon exchange bubbles, more generally 2q and 3q exchange. p p’ p p’,p’, … Developed in Collaboration between JLAB and SINP at MSU. Only available worldwide approach for extraction of resonance parameters from the p+p-p electroproduction data. V.I.Mokeev, NSTAR 2013 Workshop Peniscola, Spain, May 27-30, 2013

NΔ Magnetic Transition Form Factor and the Components of the N NΔ Magnetic Transition Form Factor and the Components of the N* Structure Magnetic Dipole Form Factor The mechanisms of the meson-baryon dressing CLAS Hall A Hall C MAMI Bates Meson- Baryon cloud bare quark core T. Sato and T-S. H. Lee, PRC 63, 055201 (2001). Successful description of ND transition form factors was achieved taking into account the contributions from the external meson-baryon cloud and the internal core of three dressed constituent quarks.

Promising potential of DSEQCD Quark Core Contribution to N→D Magnetic Form Factors from the QCD Lagrangian Quark core contribution from DSEQCD:J.Segovia, et al., arXiv:1305.0292[nucl-th]. G*M (Jones-Scardon) Q2/mr2 contact interaction. Promising potential of DSEQCD approaches in describing the quark core contribution from the first principles of QCD. contact interaction & quark anomalous magn. moment. projection for quark running mass. bare G*M inferred from exp. data within Argonne-Osaka c.c. approach.

The P11(1440) and D13(1520) Structure from the CLAS Electrocoupling Data CLAS data: D13(1520) A1/2 Np 2009 p+p-p 2012 p+p-p prelim. P11 (1440) Quark core from the quark models: P11(1440) A1/2 I.G.Aznauryan, A1/2 Quark core: E.Santopinto, M.Giannini PRC 86, 065202 (2012). PRC 76, 025212 (2007). S.Capstick and B.D.Keister, PRD 51, 3598 (1995). Consistent values of P11(1440) electrocouplings determined in independent analyses of Np and p+p-p exclusive channels strongly support reliable electrocoupling extraction. Meson-Baryon dressing: (absolute values) B,Julia-Diaz et al., PRC 77, 045205 (2008). The physics analyses of these results revealed the P11(1440) and D13(1520) structure as a combined contribution of: a) quark core as a first radial and orbital L=1 excitations of the 3-quarks, respectively and b) meson-baryon dressing.

A1/2 A3/2 Np world Np Q2=0, Npp CLAS High-Lying Resonance Electrocouplings from the p+p-p CLAS Data Analysis Δ(1700)D33 Np world Np Q2=0, CLAS Npp CLAS preliminary BF(Npp): 80-90% A1/2 V.D.Burkert, et al., PRC 67, 035204 (2003). M.Dugger, et al., PRC 79,065206 (2009). p+p-p electroproduction channel provided first preliminary results on S31(1620), S11(1650), F15(1685), D33(1700) , and P13(1720) electrocouplings of a good accuracy. A3/2 SQTM approach: I.G. Aznauryan and V.D. Burkert, Progr. Nucl. Part. Phys. 67, 1 (2012).

Conclusions and Outlook High quality meson electroproduction data from the CLAS detector allowed us to determine electrocouplings of the most excited states in the mass range of W<1.8 GeV from analyses of Np and Nh and Npp exclusive electroproduction off protons for the first time. Consistent values of gvNN* electrocouplings from independent analyses of Np/Npp and Np/Nh channels confirmed reliable extraction of these fundamental quantities. Analyses of gvNN* electrocouplings revealed the N*-structure as internal core of three constituent quarks surrounded by external meson-baryon cloud. Resonances of different quantum numbers provided complementary information on the N* structure. The data on electrocouplings of all prominent N*-states are needed. Electrocouplings of most N*-states in mass range up to 2.0 GeV will be determined in few years from analyses of Npp electroproduction at photon virtualities up to 5.0 GeV2 and will be compared with the available/future results of Np and KY exclusive electroproduction.

Conclusions and Outlook The dedicated experiment on N* studies with the CLAS12 detector at the largest photon virtualities ever achieved in exclusive meson electroproduction 5.0<Q2<12 GeV2 is tentatively scheduled for the first year of running after completion of the Jefferson Lab 12 GeV Upgrade Project. The N* program with the CLAS12 detector opens up the prospects to explore the nature of confinement and dynamical chiral symmetry breaking in baryons and to elucidate the emergence of >98 % of nucleon and N* masses from QCD. see the White Paper by I.G. Aznauryan et al., ``Studies of Nucleon Resonance Structure in Exclusive Meson Electroproduction“ published in Int. Journ. of Modern Physics E22 (2013) 133015 by the international group of theorists and experimentalists from USA, EU, Russia, Armenia, and Latin America.

Back up

The Ground and Excited Nucleon State Structure as a Key part in Exploration of Hadron Matter Nucleons and pions are the first stable composite systems of quarks and gluons generated after the Big Bang by strong interaction in non-perturbative regime. They are the building blocks of atomic nuclei The structure of the nucleon ground state from the studies of elastic form factors and different parton structure functions: Particular features of nucleon structure: infinite amount of contributing current quarks and gauge gluons; leading role of quark/gluon creation and annihilation; all constituents are substantially off-shell; important role of relativistic effects; frame-dependence of nucleon structure. Three valence current quarks (Q) embedded in the sea of gluons (g) and qq-pairs

Summary of the CLAS Data on Exclusive Meson Electroproduction off Protons in N* Excitation Region Hadronic final state Covered W-range, GeV Covered Q2-range, GeV2 C Measured observables p+n 1.1-1.40 1.1-1.55 1.1-1.7 0.15-0.40 0.3-0.6 1.7-4.2 ds/dW ds/dW, Ab p0p 0.4-0.7 0.75-6.0 ds/dW, Ab,At,Abt hp 1.5-2.0 0.2-4.0 K+L 1.65-2.35 0.65-2.55 1.4-2.6 P’ K+S0 1.7-2.1 1.8-2.5 1.7-2.6 0.5-2.55 1.5-3.50 1.8-3.50 p+p-p 1.3-1.6 1.4-2.1 0.2-0.6 0.5-1.5 Nine 1-fold differential cross sections ds/dW-CM angular distributions Ab,At,Abt-longitudinal beam, target, and beam-target asym- metries P’ –recoil polarization of strange baryon Almost full coverage of the final hadron phase space in pN, p+p-p, hp, and KY electroproduction The data are available in the CLAS Physics Data Base establiished at SINP@MSU: http://depni.sinp.msu.ru/cgi-bin/jlab/db.cgi

Data driven JLAB-MSU meson-baryon model (JM) Approaches for Extraction of gvNN* Electrocouplings from the CLAS Exclusive Meson Electroproduction Data Analyses of different meson electroproduction channels independently: p+n and p0p channels: Unitary Isobar Model (UIM) and Fixed-t Dispersion Relations (DR) I.G.Aznauryan, Phys. Rev. C67, 015209 (2003). I.G.Aznauryan et al., CLAS Coll., Phys Rev. C80, 055203 (2009). hp channel: Extension of UIM and DR I.G.Aznauryan, Phys. Rev. C68, 065204 (2003). Data fit at W<1.6 GeV, assuming S11(1535) dominance H.Denizli et al., CLAS Coll., Phys.Rev. C76, 015204 (2007). p+p-p channel: Data driven JLAB-MSU meson-baryon model (JM) V.I.Mokeev, V.D.Burkert et al., Phys. Rev. C80, 045212 (2009). V.I.Mokeev et al., CLAS Coll., Phys. Rev. C86, 035203 (2012). Global coupled-channel analyses of the CLAS/world data of pN, gvN → pN, hN, ppN, KL, KS exclusive channels: H. Kamano, S. Nakamura, T.-S. H. Lee and T. Sato, AIP Conf.Proc. 1432 (2012) 74-79. H. Kamano, S. Nakamura, T.-S. H. Lee and T. Sato, arXiv:1305.4351[nucl-th].

Mapping Dressed Quark Mass Function Description of N* electroexcitation in DSEQCD Quark mass function I.C.Cloet, C.D.Roberts, A.W.Thomas, arXiv:1304.0855[nucl-th] mpGE/GM (Q2) in DSEQCD Similar studies for the P33(1232), P11(1440), and S11(1535) electrocouplings are in progress. Elastic form factors are sensitive to momentum dependence of quark mass function. Quark mass function extracted from elastic f.f. and gvNN* electrocouploings should be the same. Data on gvNN* electrocouplings are of particular importance in order to access dressed quark mass function and dynamical structure.

N* Electroexcitation in Exclusive Meson Electroproduction off Protons Hadronic decays of prominent N*s at W<1.8 GeV. CLAS data on yields of meson electroproduction at Q2<4 GeV2 State Bran. Fract. to Np. Bran. Fract. to Nh Bran.Fract. Nππ Δ(1232)P33 0.995 N(1440)P11 0.55-0.75 0.3-0.4 N(1520)D13 0.55-0.65 0.4-0.5 N(1535)S11 0.48±0.03 0.46±0.02 D(1620)S31 0.20-0.30 0.70-0.80 N(1650)S11 0.60-0.95 0.03-0.11 0.1-0.2 N(1685)F15 0.65-0.70 0.30-0.40 Δ(1700)D33 0.8-0.9 N(1720)P13 > 0.7

The Approaches for Extraction of gvNN The Approaches for Extraction of gvNN* Electrocouplings from Np Exclusive Electroproduction off Protons The Model based on fixed-t Dispersion Relations (DR) Unitary Isobar Model (UIM) p p the real parts of 18 invariant Np electroproduction amplitudes are computed from their imaginary parts employing model independent fixed-t dispersion relations. the imaginary parts of the Np electroproduction amplitudes at W>1.3 GeV are dominated by resonant parts and were computed from N* parameters fit to the data. N N p p p N w,r,p N p N I. G.Aznauryan, Phys. Rev. C67, 015209 (2003), I.G.Aznauryan, V. D.Burkert, et al. (CLAS Collaboration), PRC 80. 055203 (2009). p+ K.Park talk, Session B4, Wednesday , May 29th , 16.15-16.40

Fits to gp→p+n Differential Cross Sections and Structure Functions DR UIM DR UIM DR w/o P11 Q2=2.44 GeV2 Q2=2.05 GeV2 ds/dWp Legendre moments Dl (l=0,1,2) from various structure functions

Quark Core vs Meson-Baryon Cloud in the Structure of P11(1440) First evaluation of the quark core contribution to the P11(1440) electrocouplings starting from QCD Lagrangian within Dyson-Schwinger Equations of QCD: D.J.Wilson, et al, Phys. Rev. C85, 025205 (2012). Poincare-covariant, symmetry preserving DSEQCD evaluation. Account for quark mass/structure formation in dressing of bare quark by gluon cloud. Simplified contact interaction generates momentum independent quark mass. A1/2 Consistent results on the quark core contribution from: DSEQCD. global meson photo-, electro-, and hadroproduction data analysis within EBAC/ Argonne-Osaka approach. Measured dressed electrocouplings are substantially different from the estimated quark core contribution. Different data analyses suggest sizable meson-baryon cloud at Q2<5.0 GeV2 which gradually decreases with Q2 .

High lying resonance electrocouplings from the p+p-p CLAS data analysis MAID analysis of Np electroproduction L.Tiator et al., Eur. Phys. J. Spec. Top. 198, 141 (2011). N (1685)F15 A1/2 BF(Np): 65-70% BF(Npp): 30-40% The results from p+p-p channel confirmed the previously available from MAID analysis of Np electroproduction Hypercentral constituent quark model by M.M.Giannini, E.Santopinto, PRC 86, 065202 (2012). Bethe-Salpeter Bonn model by M.Ronninger, B.Ch.Metsch, EPJ A49, 8 (2013). A3/2 Difference between the experimental results and QM expectations is likely related to meson-baryon cloud contributions. Evaluations of meson-baryon cloud contributiions to electrocouplings of high mass resonances are needed.

High lying resonance electrocouplings from the p+p-p CLAS data analysis Hypercentral constituent quark model by M.Giannini,E.Santopinto, PRC 86, 065202 (2012). D(1620)S31 A1/2 Bethe-Salpeter Bonn model by M.Ronninger, B.Ch.Metsch, EPJ A49, 8 (2013). Only known N*-state with dominant longitudinal electroexcitation at Q2>0.5 GeV2 . This feature is well reproduced within the framework of hypercentral quark model. Data on electrocouplings of most excited proton states in mass range up to 1.8 GeV demonstrated distinctive differences in the structure of resonances of different quantum numbers. The studies of the ground and all prominent excited state structure combined are needed in order to explore the mechanisms of the ground and N*-state formation from quarks and gluons. S1/2

CLAS12 Central Detector Forward Detector CLAS12 supports a broad program in hadronic physics. Plans to study excited baryons and mesons: Search for hybrid mesons and baryons Spectroscopy of Ξ* , Ω- N* Transition form factors at high Q2. Forward Detector

Resonance Transitions with the CLAS12 12 GeV experiment E12-09-003 will extend access to electrocouplings for all prominent N* states in the range up to Q2=12GeV2. Resonance electrocouplings in regime of quark core dominance can be related to the running quark masses and their dynamical structure. P11(1440) A1/2 Light front quark model: I.G.Aznauryan, V.D. Burkert, PRC85, 055202 (2012). accessible at 6 GeV LQCD DSE quark mass (GeV) accessible at 12 GeV DSEQCD : contact inte- raction; realistic QCD interaction. CLAS12 projected Probe the transition from confinement to pQCD regimes, allowing us to explore how confinement in baryons emerge from QCD and how >98 % of baryon masses are generated non-perturbatively via dynamical chiral symmetry breaking.

Impact of the Recent LQCD studies of N* Spectrum and Structure on the N* Program with CLAS/CLAS12 J.J.Dudek, R.G.Edwards, Phys. Rev. D85, 054016 (2012). each N* state with MN* <1.8 GeV has partner in computed LQCD spectrum, but level ordering is not always consistent to the data wave functions of the low-lying N* states dominate by 1-2 SU(6) configurations, while the wave function of high lying N*’s may contain many SU(6) configurations presence of hybrid-N*s with dominant contribution of hybrid components at MN*>1.9 GeV marked by Should be verified by experiment ! New direction in N* studies proposed in V.D.Burkert, arXiv:1203.2373 [nucl-ex]: Search for hybrid N*-states looking for: overpopulation of SU(6)-multiplet; particular behavior of gvNN* electrocouplings, which reflects presence of the hybrid component.

Resonant /non-resonant contributions from the fit of p+p-p electroproduction cross sections within the JM model W=1.51 GeV, Q2=0.38 GeV2 W=1.51 GeV, Q2=0.43 GeV2 Reliable isolation of the resonant cross sections is achieved full cross sections within the JM model resonant part non-resonant part

Transition N-P11(1440) form factors in LQCD Includes the quark loops in the sea , which are critical in order to reproduce the CLAS data at Q2<1.0 GeV2 A1/2, S1/2 => F1*, F2* Mπ = 390, 450, 875 MeV L box =3.0, 2.5, 2.5 f H.W. Lin and S.D. Cohen, arXiv:1108.2528 CLAS data Exploratory LQCD results provide reasonable description of the CLAS data from the QCD Lagrangian. Prospects for LQCD evaluation with improved projection operators, approaching physical mp in the box of appropriate size.