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Fissum, Kevin; Liang, M.; Anderson, B. D.; Aniol, K.; Auerbach, L.; Baker, F. T.; Berthot, J.; Bertozzi, W.; Bertin, P.Y.; Bimbot, L.; Boeglin, W.; Brash, E. J.; Breton, Vincent; Breuer, H.; Burtin, E.; Calarco, J. R.; Cardman, L.; Cates, G. D.; Cavata, C.; Cc, Chang; Chen, J. P.; Cisbani, E.; Dale, D.; Jager, C. W. de; Лео, Р. Де; Deur, A.; Diederich, B.; Djawotho, P.; Domingo, J.; Ducret, J.E.; Epstein, M. B.; Ewell, L.; Finn, J. M.; Fonvieille, H.; Frois, B.; Frullani, S.; Gao, J.; Garibaldi, F.; Gasparian, A.; Gilad, S.; Gilman, R.; Glamazdin, A.; Glashausser, C.; Gómez, J.; Gorbenko, V.; Gorringe, T. P.; Hersman, F. W.; Holmes, R.; Holtrop, M.; d’Hose, N.; Howell, C. R.; Huber, G. M.; Hyde‐Wright, C. E.; Iodice, M.; Jaminion, S.; Jones, M.; Joo, K.; Jutier, C.; Kahl, W.; Kato, S.; Kelly, James; Kerhoas, S.; Khandaker, M.; Khayat, M.; Kino, K.; Korsch, W.; Kramer, L.; Kumar, Krishna; Kumbartzki, G.; Laveissière, G.; Leone, A.; LeRose, J.; Levchuk, L.; Lindgren, R.; Liyanage, N.; Lolos, G. J.; Lourie, R. W.; Madey, R.; Maeda, K.; Malov, S.; Manley, D. M.; Margaziotis, D. J.; Markowitz, P.; Martino, J.; McCarthy, J.; McCormick, K.; McIntyre, Justin I.; Meer, R. L. J. van der; Meziani, Z. E.; Michaels, R.; Mougey, J.; Nanda, S.; Neyret, D.; Offermann, E.A.J.M.; Papandreou, Z.; Perdrisat, C. F.; Perrino, R.; Petratos, G. G.; Platchkov, S.; Pomatsalyuk, R.; Prout, D. L.; Punjabi, V.; Pussieux, T.; Qúeḿener, G.; Ransome, R. D.; Ravel, O.; Roblin, Y.; Roché, R.; Rowntree, D.; Rutledge, G.; Rutt, P. M.; Saha, A.; Saito, T.; Sarty, A. J.; Serdarevic-Offermann, A.; Smith, T.; Soldi, A.; Sorokin, P.; Souder, P. A.; Suleiman, R.; Templon, J. A.; Terasawa, T.; Todor, L.; Tsubota, H.; Ueno, Hiroaki; Ulmer, P. E.; Urciuoli, G. M.; Vernin, P.; Verst, S. Van; Vlahović, Branislav; Voskanyan, H.; Watson, J. W.; Weinstein, L. B.; Wijesooriya, K.; Wojtsekhowski, B.; Zainea, D. G.; Zeps, V.; Zhao, J.; Zhou, Zhengfang; Udı́as, J. M.; Vignote, J. R.; Ryckebusch, Jan; Debruyne, Dimitri

doi:10.1103/physrevc.70.034606

Cited by 35 publications

(16 citation statements)

References 101 publications

(136 reference statements)

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“…meson coupling, QMC) used the MIT bag model to represent the three confined quarks in the proton (Guichon, 1988;Guichon et al, 1996;Stone et al, 2016). Later work used the QMC model with more general confinement mechanisms (Blunden and Miller, 1996), the covariant NJL model (Cloet et al, 2009a(Cloet et al, , 2006(Cloet et al, , 2016 and the chiral quark soliton model (Diakonov et al, 1996;Smith and Miller, 2003, 2004. In these models the attraction needed to produce a bound state is generated by the exchange of scalar quantum numbers (either by a scalar meson (Guichon, 1988;Guichon et al, 1996;Stone et al, 2016) or by pairs of pions (Smith and Miller, 2003, 2004) and the repulsion needed to obtain nuclear saturation is caused by exchange of vector mesons.…”

Section: Fig 30: (Color Online)mentioning

confidence: 99%

Nucleon-nucleon correlations, short-lived excitations, and the quarks within

et al. 2017

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This article reviews our current understanding of how the internal quark structure of a nucleon bound in nuclei differs from that of a free nucleon. We focus on the interpretation of measurements of the EMC effect for valence quarks, a reduction in the Deep Inelastic Scattering (DIS) cross-section ratios for nuclei relative to deuterium, and its possible connection to nucleon-nucleon Short-Range Correlations (SRC) in nuclei. Our review and new analysis (involving the amplitudes of non-nucleonic configurations in the nucleus) of the available experimental and theoretical evidence shows that there is a phenomenological relation between the EMC effect and the effects of SRC that is not an accident. The influence of strongly correlated neutron-proton pairs involving highly virtual nucleons is responsible for both effects. These correlated pairs are temporary high-density fluctuations in the nucleus in which the internal structure of the nucleons is briefly modified. This conclusion needs to be solidified by the future experiments and improved theoretical analyses that are discussed herein.

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Section: Fig 30: (Color Online)mentioning

confidence: 99%

Nucleon-nucleon correlations, short-lived excitations, and the quarks within

et al. 2017

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“…data for electron scattering off 12 C and 16 O [46,47] and we adopted this program for neutrino reaction [33].…”

Section: B Modelsmentioning

confidence: 99%

Quasi-elastic neutrino charged-current scattering off medium-heavy nuclei:40Ca and40Ar

Butkevich¹

2012

Phys. Rev. C

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The charged-current quasi-elastic scattering of muon neutrinos on calcium and argon targets is calculated for neutrino energy up to 2.8 GeV. The calculations are done within the framework of the relativistic distorted-wave impulse approximation, which was earlier successfully applied to describe electron-nucleus data. The model is first tested against experimental data for electron scattering off calcium and then it is applied to calculate (anti)neutrino cross sections on 40 Ca and 40 Ar. We show that reduced exclusive cross sections for neutrino and electron scattering are similar. A significant nuclear model dependence of both inclusive and total cross sections for energy about 1 GeV was found. From the comparison of the (anti)neutrino differential and total cross sections per (proton)neutron, calculated for the carbon, oxygen, and argon targets it is evident that the cross sections decrease slowly with the mass-number of the target due to nuclear effects.

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“…Nucleon knockout experiments, while confirming the validity of the shell model, have unambiguously shown its limitations. Owing to strong correlations, nucleons are excited to states of higher energy and the occupation of the shell-model states is reduced to values sizably less than 1 [43][44][45]. Moreover, their energy distribution acquires finite widths, reflecting the finite lifetime of singleparticle states [46,47].…”

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confidence: 99%

Neutron knockout in neutral-current neutrino-oxygen interactions

Ankowski

Benhar

2013

Phys. Rev. D

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The ongoing and future searches for diffuse supernova neutrinos and sterile neutrinos carried out with large water-Cherenkov detectors require a precise determination of the backgrounds, especially those involving γ rays. Of great importance, in this context, is the process of neutron knockout through neutral-current scattering of atmospheric neutrinos on oxygen. Nuclear reinteractions of the produced neutron may in fact lead to the production of γ rays of energies high enough to mimic the processes of interest. In this article, we focus on the kinematical range suitable for simulations of atmospheric-neutrino interactions and provide the neutron-knockout cross sections computed using the formalism based on the realistic nuclear spectral function. The role of the strange-quark contribution to the neutral-current axial form factor is also analyzed. Based on the available experimental information, we give an estimate of the associated uncertainty. The detection of the antineutrino burst from the 1987A core-collapse supernova in the Large Magellanic Cloud by three independent experiments [1-3] marked the dawn of a new era in observational astronomy. That measurement, totaling 24 events, was feasible owing to not-too far distance from the collapsing star and to the extreme nature of supernova explosions. While the gravitational energy released in the act of collapse is ∼200-300 times higher than that produced by the Sun over its entire lifetime, ∼99% of it is radiated over a time scale of a few tens of seconds in the form of an immense flux of low-energy neutrinos [4].Supernovae have long been recognized as unique laboratories to study a number of fundamental physics issues [5]. The scarcity of the available data seems, however, to be an insuperable problem, because the frequency of the core-collapse events within our Galaxy is estimated to be 1.9 ± 1.1 per century [6].On the other hand, during the lifetime of the Milky Way, those phenomena have occurred approximately 100 million times, and the Universe witnesses them at the rate of approximately one per second [7]. All the past core-collapse supernovae have contributed to a diffuse supernova-neutrino (DSN) flux, which is expected to be tiny but continuous in time. Its detection may provide a great deal of information, complementary to that from the future neutrino bursts.Although its detailed features show some model dependence, it is rather well established that the predicted DSN spectrum has a peak at the value of 4-7 MeV with an exponential drop at higher energy [8]. In the low-energy region, E ν 8-12 MeV, the DSN signal is not accessible owing to an overwhelming flux of reactorν e . On the other hand, in the high-energy region, E ν 30-40 MeV, it is covered by the ν andν flux of atmospheric origin [8- * Present address: Department of Physics, Okayama University, Okayama 700-8530, Japan; Artur.Ankowski@roma1.infn.it † Omar.Benhar@roma1.infn.it 10]. Moreover, at E ν 16 (19) MeV, the solar neutrino flux from the 8 B (hep) chain dominates over the DSN flux. Therefor...

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Dynamics of the quasielasticO16(e,e′p)reaction at
Kevin Fissum¹,
M. Liang²,
B. D. Anderson³
et al.

Cited by 35 publications

References 101 publications

Nucleon-nucleon correlations, short-lived excitations, and the quarks within

Nucleon-nucleon correlations, short-lived excitations, and the quarks within

Quasi-elastic neutrino charged-current scattering off medium-heavy nuclei:40Ca and40Ar

Neutron knockout in neutral-current neutrino-oxygen interactions

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Dynamics of the quasielasticO16(e,e′p)reaction atKevin Fissum1, M. Liang2, B. D. Anderson3 et al.

Cited by 35 publications

References 101 publications

Nucleon-nucleon correlations, short-lived excitations, and the quarks within

Nucleon-nucleon correlations, short-lived excitations, and the quarks within

Quasi-elastic neutrino charged-current scattering off medium-heavy nuclei:40Ca and40Ar

Neutron knockout in neutral-current neutrino-oxygen interactions

Contact Info

Product

Resources

About

Dynamics of the quasielasticO16(e,e′p)reaction at
Kevin Fissum¹,
M. Liang²,
B. D. Anderson³
et al.