Measurements of 
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 cross sections with CLAS at 
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Isupov, E. L.; Burkert, Volker; Carman, D. S.; Gothe, R. W.; Hicks, K.; Ишханов, Б. С.; Mokeev, V.; Adhikari, K. P.; Adhikari, S.; Adikaram, D.; Akbar, Z.; Amaryan, M. J.; Pereira, S. Anefalos; Avakian, H.; Ball, J.; Baltzell, N. A.; Battaglieri, M.; Batourine, V.; Bedlinskiy, I.; Biselli, A. S.; Briscoe, W. J.; Brooks, W. K.; Bültmann, S.; Cao, T.; Celentano, A.; Charles, G.; Chetry, T.; Ciullo, G.; Clark, L.; Colaneri, L.; Cole, P. L.; Contalbrigo, M.; Cortes, O.; Credé, V.; D’Angelo, A.; Dashyan, N.; Vita, R. De; Sanctis, E. De; Deur, A.; Djalali, C.; Dupré, R.; Alaoui, A. El; Fassi, L. El; Elouadrhiri, L.; Eugenio, P.; Fedotov, G.; Fersch, R.; Filippi, A.; Fleming, J. A.; Forest, T. A.; Garçon, M.; Gavalian, G.; Ghandilyan, Y.; Gilfoyle, G. P.; Giovanetti, K. L.; Girod, F. X.; Glazier, D. I.; Gleason, C.; Golovatch, E.; Griffioen, K. A.; Guidal, M.; Guo, L. B.; Hafidi, K.; Hakobyan, H.; Hanretty, C.; Harrison, N.; Hattawy, M.; Heddle, D.; Holtrop, M.; Hughes, S. M.; Ilieva, Y.; Ireland, D. G.; Jenkins, D.; Jiang, Hao; Joo, K. S.; Joosten, S.; Keller, D.; Khachatryan, G.; Khandaker, M.; Kim, A.; Kim, W.; Klein, A.; Klein, Frank; Kubarovsky, V.; Kuleshov, S. V.; Kunkel, Michael; Lanza, L.; Lenisa, P.; Livingston, K.; Lu, H. Y.; MacGregor, I. J. D.; Markov, N.; McKinnon, B.; Mineeva, T.; Mirazita, M.; Montgomery, R. A.; Movsisyan, A.; Munévar, E.; Camacho, C. Muñoz; Murdoch, G.; Nadel-Turoński, P.; Niccolai, S.; Niculescu, G.; Niculescu, I.; Osipenko, M.; Paolone, M.; Paremuzyan, R.; Park, K.; Pasyuk, E.; Phelps, W.; Pogorelko, O.; Price, J. W.; Procureur, S.; Prok, Y.; Protopopescu, D.; Raue, B. A.; Ripani, M.; Riser, D.; Ritchie, B. G.; Rizzo, A.; Sabatié, F.; Salgado, C.; Schumacher, R. A.; Sharabian, Y. G.; Simonyan, A.; Skorodumina, Iu.; Smith, G. D.; Sokhan, D.; Sparveris, N.; Stanković, Ivana; Strakovsky, I. I.; Strauch, S.; Taiuti, M.; Tian, Ye; Torayev, B.; Trivedi, A.; Ungaro, M.; Voskanyan, H.; Voutier, E.; Walford, N. K.; Wei, Xin; Wood, M. H.; Zachariou, N.; Zhang, J.

doi:10.1103/physrevc.96.025209

Cited by 41 publications

(45 citation statements)

References 36 publications

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“…and γ * n → R 0 (dashed green curves). In all cases, the results on x ∈ [6,12] are projections, obtained via extrapolation of analytic approximations to our results on x ∈ [0, 6] (see Ref. [59] for details).…”

Section: Discussionmentioning

confidence: 99%

“…Moreover, QCD-based approaches that compute form factors at large photon virtualities are needed because the so-called meson-cloud often screens the dressed-quark core of all baryons at low momenta [8,9]. On the experimental side, a substantial progress has been made in the extraction of transition electrocouplings, g vN N * , from meson electroproduction data, obtained primarily with the CLAS detector at the Jefferson Laboratory (JLab) [3,[10][11][12][13][14][15]. This manuscript is arranged as follows.…”

Section: Introductionmentioning

confidence: 99%

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Structure of the Nucleon and Its First Radial Excitation

Segovia

2019

Few-Body Syst

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Structure of the Nucleon and Its First Radial Excitation

Segovia

2019

Few-Body Syst

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“…Furthermore, the data for ∆(1620)1/2 − , N (1720) 3/2 + , N (1720) 3/2 + and ∆(1700) 3/2 − cover a smaller range of Q 2 < 1.5 GeV 2 when compared to the other resonances, Q 2 < 5 GeV 2 . For these resonances, we have preliminary estimates of the central electrocoupling values [43] based on the good description of the π + π − p electroproduction data off protons from CLAS at 2.0 GeV 2 < Q 2 < 5.0 GeV 2 [58][59][60]. We give a conservative extrapolation uncertainty estimate for these resonance electrocouplings of at least 20% (when the relative error as calculated above is smaller).…”

Section: Formalismmentioning

confidence: 99%

Nucleon resonance contributions to unpolarized inclusive electron scattering

et al. 2019

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The first CLAS12 experiments will provide high-precision data on inclusive electron scattering observables at a photon virtuality Q 2 ranging from 0.05 GeV 2 to 12 GeV 2 and center-of-mass energies W up to 4 GeV. In view of this endeavour, we present the modeling of the resonant contributions to the inclusive electron scattering observables. As input, we use the existing CLAS electrocoupling results obtained from exclusive meson electroproduction data off protons, and evaluate for the first time the resonant contributions based on the experimental results on the nucleon resonance electroexcitation. The uncertainties are given by the data and duly propagated through a Monte Carlo approach. In this way, we obtain estimates for the resonant contributions, important for insight into the nucleon parton distributions in the resonance region and for the studies of quarkhadron duality.

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“…To this end, a systematic analysis of the data collected on various nuclear targets by different experiments using the CLAS detector in Hall B at Jefferson Laboratory, while not completely addressing the requirements outlined above, would be an important advance. So far, the published studies focused on specific hadronic processes with hydrogen targets [42][43][44][45][46][47][48][49]. These should already be useful for testing generator models for certain hadronic processes, such as ρ meson production through higher resonances.…”

Section: Electron Scattering Measurements and Neutrino Cross Sectmentioning

confidence: 99%

Lepton-nucleus cross section measurements for DUNE with the LDMX detector

Ankowski

Friedland

et al. 2020

Phys. Rev. D

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We point out that the LDMX (Light Dark Matter eXperiment) detector design, conceived to search for sub-GeV dark matter, will also have very advantageous characteristics to pursue electron-nucleus scattering measurements of direct relevance to the neutrino program at DUNE and elsewhere. These characteristics include a 4-GeV electron beam, a precision tracker, electromagnetic and hadronic calorimeters with near 2π azimuthal acceptance from the forward beam axis out to ∼40 • angle, and low reconstruction energy threshold. LDMX thus could provide (semi)exclusive cross-section measurements, with detailed information about final-state electrons, pions, protons, and neutrons. We compare the predictions of two widely-used neutrino generators (genie, gibuu) in the LDMX region of acceptance to illustrate the large modeling discrepancies in electron-nucleus interactions at DUNE-like kinematics. We argue that discriminating between these predictions is well within the capabilities of the LDMX detector.

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Measurements of ep→e′π+π−p′ cross sections with CLAS at 1.40

Cited by 41 publications

References 36 publications

Structure of the Nucleon and Its First Radial Excitation

Structure of the Nucleon and Its First Radial Excitation

Nucleon resonance contributions to unpolarized inclusive electron scattering

Lepton-nucleus cross section measurements for DUNE with the LDMX detector

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