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1. The Present and Future of QCD

Author

Achenbach, P., Adhikari, D., Afanasev, A., Afzal, F., Aidala, C. A., Al-bataineh, A., Almaalol, D. K., Amaryan, M., Androić, D., Armstrong, W. R., Arratia, M., Arrington, J., Asaturyan, A., Aschenauer, E. C., Atac, H., Avakian, H., Averett, T., Gayoso, C. Ayerbe, Bai, X., Barish, K. N., Barnea, N., Basar, G., Battaglieri, M., Baty, A. A., Bautista, I., Bazilevsky, A., Beattie, C., Behera, S. C., Bellini, V., Bellwied, R., Benesch, J. F., Benmokhtar, F., Bernardes, C. A., Bernauer, J. C., Bhatt, H., Bhatta, S., Boer, M., Boettcher, T. J., Bogacz, S. A., Bossi, H. J., Brandenburg, J. D., Brash, E. J., Briceño, R. A., Briscoe, W. J., Brodsky, S. J., Brown, D. A., Burkert, V. D., Caines, H., Cali, I. A., Camsonne, A., Carman, D. S., Caylor, J., Cerci, S., Llatas, M. Chamizo, Chatterjee, S., Chen, J. P., Chen, Y., Chen, Y. -C., Chien, Y. -T., Chou, P. -C., Chu, X., Chudakov, E., Cline, E., Cloët, I. C., Cole, P. L., Connors, M. E., Constantinou, M., Cosyn, W., Dusa, S. Covrig, Cruz-Torres, R., D'Alesio, U., da Silva, C., Davoudi, Z., Dean, C. T., Dean, D. J., Demarteau, M., Deshpande, A., Detmold, W., Deur, A., Devkota, B. R., Dhital, S., Diefenthaler, M., Dobbs, S., Döring, M., Dong, X., Dotel, R., Dow, K. A., Downie, E. J., Drachenberg, J. L., Dumitru, A., Dunlop, J. C., Dupre, R., Durham, J. M., Dutta, D., Edwards, R. G., Ehlers, R. J., Fassi, L. El, Elaasar, M., Elouadrhiri, L., Engelhardt, M., Ent, R., Esumi, S., Evdokimov, O., Eyser, O., Fanelli, C., Fatemi, R., Fernando, I. P., Flor, F. A., Fomin, N., Frawley, A. D., Frederico, T., Fries, R. J., Gal, C., Gamage, B. R., Gamberg, L., Gao, H., Gaskell, D., Geurts, F., Ghandilyan, Y., Ghimire, N., Gilman, R., Gleason, C., Gnanvo, K., Gothe, R. W., Greene, S. V., Grießhammer, H. W., Grossberndt, S. K., Grube, B., Hackett, D. C., Hague, T. J., Hakobyan, H., Hansen, J. -O., Hatta, Y., Hattawy, M., Havener, L. B., Hen, O., Henry, W., Higinbotham, D. W., Hobbs, T. J., Hodges, A. M., Holmstrom, T., Hong, B., Horn, T., Howell, C. R., Huang, H. Z., Huang, M., Huang, S., Huber, G. M., Hyde, C. E., Isupov, E. L., Jacobs, P. M., Jalilian-Marian, J., Jentsch, A., Jheng, H., Ji, C. -R., Ji, X., Jia, J., Jones, D. C., Jones, M. K., Kalantarians, N., Kalicy, G., Kang, Z. B., Karthein, J. M., Keller, D., Keppel, C., Khachatryan, V., Kharzeev, D. E., Kim, H., Kim, M., Kim, Y., King, P. M., Kinney, E., Klein, S. R., Ko, H. S., Koch, V., Kohl, M., Kovchegov, Y. V., Krintiras, G. K., Kubarovsky, V., Kuhn, S. E., Kumar, K. S., Kutz, T., Lajoie, J. G., Lauret, J., Lavrukhin, I., Lawrence, D., Lee, J. H., Lee, K., Lee, S., Lee, Y. -J., Li, S., Li, W., Li, Xiaqing, Li, Xuan, Liao, J., Lin, H. -W., Lisa, M. A., Liu, K. -F., Liu, M. X., Liu, T., Liuti, S., Liyanage, N., Llope, W. J., Loizides, C., Longo, R., Lorenzon, W., Lunkenheimer, S., Luo, X., Ma, R., McKinnon, B., Meekins, D. G., Mehtar-Tani, Y., Melnitchouk, W., Metz, A., Meyer, C. A., Meziani, Z. -E., Michaels, R., Michel, J. K. L., Milner, R. G., Mkrtchyan, H., Mohanmurthy, P., Mohanty, B., Mokeev, V. I., Moon, D. H., Mooney, I. A., Morningstar, C., Morrison, D. P., Müller, B., Mukherjee, S., Mulligan, J., Camacho, C. Munoz, Quijada, J. A. Murillo, Murray, M. J., Nadeeshani, S. A., Nadel-Turonski, P., Nam, J. D., Nattrass, C. E., Nijs, G., Noronha, J., Noronha-Hostler, J., Novitzky, N., Nycz, M., Olness, F. I., Osborn, J. D., Pak, R., Pandey, B., Paolone, M., Papandreou, Z., Paquet, J. -F., Park, S., Paschke, K. D., Pasquini, B., Pasyuk, E., Patel, T., Patton, A., Paudel, C., Peng, C., Peng, J. C., Da Costa, H. Pereira, Perepelitsa, D. V., Peters, M. J., Petreczky, P., Pisarski, R. D., Pitonyak, D., Ploskon, M. A., Posik, M., Poudel, J., Pradhan, R., Prokudin, A., Pruneau, C. A., Puckett, A. J. R., Pujahari, P., Putschke, J., Pybus, J. R., Qiu, J. -W., Rajagopal, K., Ratti, C., Read, K. F., Reed, R., Richards, D. G., Riedl, C., Ringer, F., Rinn, T., West, J. Rittenhouse, Roche, J., Rodas, A., Roland, G., Romero-López, F., Rossi, P., Rostomyan, T., Ruan, L., Ruimi, O. M., Saha, N. R., Sahoo, N. R., Sakaguchi, T., Salazar, F., Salgado, C. W., Salmè, G., Salur, S., Santiesteban, S. N., Sargsian, M. M., Sarsour, M., Sato, N., Satogata, T., Sawada, S., Schäfer, T., Scheihing-Hitschfeld, B., Schenke, B., Schindler, S. T., Schmidt, A., Seidl, R., Shabestari, M. H., Shanahan, P. E., Shen, C., Sheng, T. -A., Shepherd, M. R., Sickles, A. M., Sievert, M. D., Smith, K. L., Song, Y., Sorensen, A., Souder, P. A., Sparveris, N., Srednyak, S., Leiton, A. G. Stahl, Stasto, A. M., Steinberg, P., Stepanyan, S., Stephanov, M., Stevens, J. R., Stewart, D. J., Stewart, I. W., Stojanovic, M., Strakovsky, I., Strauch, S., Strickland, M., Cerci, D. Sunar, Suresh, M., Surrow, B., Syritsyn, S., Szczepaniak, A. P., Tadepalli, A. S., Tang, A. H., Takaki, J. D. Tapia, Tarnowsky, T. J., Tawfik, A. N., Taylor, M. I., Tennant, C., Thiel, A., Thomas, D., Tian, Y., Timmins, A. R., Tribedy, P., Tu, Z., Tuo, S., Ullrich, T., Umaka, E., Upton, D. W., Vary, J. P., Velkovska, J., Venugopalan, R., Vijayakumar, A., Vitev, I., Vogelsang, W., Vogt, R., Vossen, A., Voutier, E., Vovchenko, V., Walker-Loud, A., Wang, F., Wang, J., Wang, X., Wang, X. -N., Weinstein, L. B., Wenaus, T. J., Weyhmiller, S., Wissink, S. W., Wojtsekhowski, B., Wong, C. P., Wood, M. H., Wunderlich, Y., Wyslouch, B., Xiao, B. W., Xie, W., Xiong, W., Xu, N., Xu, Q. H., Xu, Z., Yaari, D., Yao, X., Ye, Z., Ye, Z. H., Yero, C., Yuan, F., Zajc, W. A., Zhang, C., Zhang, J., Zhao, F., Zhao, Y., Zhao, Z. W., Zheng, X., Zhou, J., and Zurek, M.

Subjects
High Energy Physics - Phenomenology, High Energy Physics - Experiment, Nuclear Experiment, Nuclear Theory
Abstract

This White Paper presents the community inputs and scientific conclusions from the Hot and Cold QCD Town Meeting that took place September 23-25, 2022 at MIT, as part of the Nuclear Science Advisory Committee (NSAC) 2023 Long Range Planning process. A total of 424 physicists registered for the meeting. The meeting highlighted progress in Quantum Chromodynamics (QCD) nuclear physics since the 2015 LRP (LRP15) and identified key questions and plausible paths to obtaining answers to those questions, defining priorities for our research over the coming decade. In defining the priority of outstanding physics opportunities for the future, both prospects for the short (~ 5 years) and longer term (5-10 years and beyond) are identified together with the facilities, personnel and other resources needed to maximize the discovery potential and maintain United States leadership in QCD physics worldwide. This White Paper is organized as follows: In the Executive Summary, we detail the Recommendations and Initiatives that were presented and discussed at the Town Meeting, and their supporting rationales. Section 2 highlights major progress and accomplishments of the past seven years. It is followed, in Section 3, by an overview of the physics opportunities for the immediate future, and in relation with the next QCD frontier: the EIC. Section 4 provides an overview of the physics motivations and goals associated with the EIC. Section 5 is devoted to the workforce development and support of diversity, equity and inclusion. This is followed by a dedicated section on computing in Section 6. Section 7 describes the national need for nuclear data science and the relevance to QCD research., Comment: QCD Town Meeting White Paper, as submitted to 2023 NSAC LRP committee on Feb. 28, 2023

Published
2023
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2. Correlated Fermion Pairs in Nuclei and Ultracold Atomic Gases

Author

Hen, O., Weinstein, L. B., Piasetzky, E., Miller, G. A., Sargsian, M. M., and Sagi, Y.

Subjects
Nuclear Experiment, Condensed Matter - Quantum Gases, Nuclear Theory
Abstract

Background: The high momentum distribution of atoms in two spin-state ultra-cold atomic gases with strong short-range interactions between atoms with different spins, which can be described using Tan's contact, are dominated by short range pairs of different fermions and decreases as $k^{-4}$. In atomic nuclei the momentum distribution of nucleons above the Fermi momentum ($k>k_F \approx 250$ Mev/c) is also dominated by short rangecorrelated different-fermion (neutron-proton) pairs. Purpose: Compare high-momentum unlike-fermion momentum distributions in atomic and nuclear systems. Methods: We show that, for $k>k_F$ MeV/c, nuclear momentum distributions are proportional to that of the deuteron. We then examine the deuteron momentum distributions derived from a wide variety of modern nucleon-nucleon potentials that are consistent with $NN$-scattering data. Results: The high momentum tail of the deuteron momentum distribution, and hence of the nuclear momentum distributions appears to decrease as $k^{-4}$. This behavior is shown to arise from the effects of the tensor part of the nucleon-nucleon potential. In addition, when the dimensionless interaction strength for the atomic system is chosen to be similar to that of atomic nuclei, the probability for finding a short range different-fermion pair in both systems is the same. Conclusions: Although nuclei do not satisfy all of the conditions for Tan's contact, the observed similarity of the magnitude and $k^{-4}$ shape of nuclear and atomic momentum distributions is remarkable because these systems differ by about $20$ orders of magnitude in density. This similarity may lead to a greater understanding of nuclei and the density dependence of nuclear systems., Comment: Accepted for publication in PRC. 8 pages, 3 figures, 1 table. Revised version: 6-Oct-15

Published
2014
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3. Measurement of the neutron electric to magnetic form factor ratio at Q2 = 1.58 GeV2 using the reaction 3He(e,e'n)pp

Author

Schlimme, B. S., Achenbach, P., Gayoso, C. A. Ayerbe, Bernauer, J. C., Böhm, R., Bosnar, D., Challand, Th., Distler, M. O., Doria, L., Fellenberger, F., Fonvieille, H., Rodríguez, M. Gómez, Grabmayr, P., Hehl, T., Heil, W., Kiselev, D., Krimmer, J., Makek, M., Merkel, H., Middleton, D. G., Müller, U., Nungesser, L., Ott, B. A., Pochodzalla, J., Potokar, M., Majos, S. Sánchez, Sargsian, M. M., Sick, I., Širca, S., Weinriefer, M., Wendel, M., and Yoon, C. J.

Subjects
Nuclear Experiment
Abstract

A measurement of beam helicity asymmetries in the reaction 3He(e,e'n)pp has been performed at the Mainz Microtron in quasielastic kinematics in order to determine the electric to magnetic form factor ratio of the neutron, GEn/GMn, at a four momentum transfer Q2 = 1.58 GeV2. Longitudinally polarized electrons were scattered on a highly polarized 3He gas target. The scattered electrons were detected with a high-resolution magnetic spectrometer, and the ejected neutrons with a dedicated neutron detector composed of scintillator bars. To reduce systematic errors data were taken for four different target polarization orientations allowing the determination of GEn/GMn from a double ratio. We find mu_n GEn/GMn = 0.250 +/- 0.058(stat.) +/- 0.017 (sys.).

Published
2013
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4. Coherent Vector Meson Photo-Production from Deuterium at Intermediate Energies

Author

Rogers, T. C., Sargsian, M. M., and Strikman, M. I.

Subjects
High Energy Physics - Phenomenology
Abstract

We analyze the cross section for vector meson photo-production off a deuteron for the intermediate range of photon energies starting at a few GeVs above the threshold and higher. We reproduce the steps in the derivation of the conventional non-relativistic Glauber expression based on an effective diagrammatic method while making corrections for Fermi motion and intermediate energy kinematic effects. We show that, for intermediate energy vector meson production, the usual Glauber factorization breaks down and we derive corrections to the usual Glauber method to linear order in longitudinal nucleon momentum. The purpose of our analysis is to establish methods for probing interesting physics in the production mechanism for phi-mesons and heavier vector mesons. We demonstrate how neglecting the breakdown of Glauber factorization can lead to errors in measurements of basic cross sections extracted from nuclear data., Comment: 41 pages, 13 figures, figure 9 is compressed from previous version, typos fixed

Published
2005
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5. Measurement of 2- and 3-Nucleon Short Range Correlation Probabilities in Nuclei

Author

Egiyan, K. S., Dashyan, N. B., Sargsian, M. M., Strikman, M. I., Weinstein, L. B., and Collaboration, CLAS

Subjects
Nuclear Experiment
Abstract

The ratios of inclusive electron scattering cross sections of He4, C12 and Fe56 to He3 have been measured at 1 < x_B < 3. At Q^2 > 1.4 GeV^2, the ratios exhibit two separate plateaus, at 1.5 < x_B < 2 and at x_B > 2.25. This pattern is predicted by models that include 2- and 3-nucleon short-range correlations (SRC). Relative to A=3, the per-nucleon probabilities of 3-nucleon SRC are 2.3, 3.2, and 4.6 times larger for A=4, 12 and 56. This is the first measurement of 3-nucleon SRC probabilities in nuclei. \\, Comment: 5 pages, 1 figure

Published
2005
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6. Exclusive Electro-Disintegration of 3He at high Q2: II. Decay Function Formalism

Author

Sargsian, M. M., Abrahamyan, T. V., Frankfurt, L. L., and Strikman, M. I.

Subjects
Nuclear Theory
Abstract

Based on the theoretical framework of generalized eikonal approximation we study the two-nucleon emission reactions in high $Q^2$ electro-disintegration of $^3He$. Main aim is to investigate those features of the reaction which can be unambiguously identified with the short range properties of the ground state nuclear wave function. To evaluate the differential cross section we work in the formalism of the decay function which characterizes the property of the ground state wave function as well as the decay properties of final two nucleon spectator system. Our main motivation here is to explore the accessibility of two-- and three--nucleon short range correlations in $^3$He as well as to isolate unambiguously single and double rescattering processes in the reaction dynamics. Our analysis allowed us also to identify new approaches for investigating the role of the practically unknown three-nucleon forces in the ground state wave function of $^3He$., Comment: 37 pages, 28 figures

Published
2005
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7. Exclusive Electro-Disintegration of 3He at High Q2: I. Generalized Eikonal Approximation

Author

Sargsian, M. M., Abrahamyan, T. V., Strikman, M. I., and Frankfurt, L. L.

Subjects
Nuclear Theory
Abstract

We develop a theoretical framework for calculation of high $Q^2$ exclusive electro-disintegration of A=3 systems. The main result of this work is the calculation of the final state interaction of the struck energetic nucleon with recoil nucleons within the generalized eikonal approximation (GEA) which allows us to account for the finite and relatively large momenta of the bound nucleons in the nucleus. The important advantage of this approach is the possibility to study in a self-consistent way the short range correlations in nuclei. This is due to the fact that GEA does not require a stationary condition for recoil nucleons as conventional Glauber approximation does. As a result GEA treats explicitly the Fermi motion of recoil nucleons in the nucleus., Comment: 16 pages and 4 figures. To be published in Physical Review C

Published
2004
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8. Hadrons in the Nuclear Medium

Author

Sargsian, M. M., Arrington, J., Bertozzi, W., Boeglin, W., Carlson, C. E., Day, D. B., Frankfurt, L. L., Egiyan, K., Ent, R., Gilad, S., Griffioen, K., Higinbotham, D. W., Kuhn, S., Melnitchouk, W., Miller, G. A., Piasetzky, E., Stepanyan, S., Strikman, M. I., and Weinstein, L. B.

Subjects
Nuclear Theory, High Energy Physics - Experiment, High Energy Physics - Phenomenology, Nuclear Experiment
Abstract

Quantum Chromodynamics, the microscopic theory of strong interactions, has not yet been applied to the calculation of nuclear wave functions. However, it certainly provokes a number of specific questions and suggests the existence of novel phenomena in nuclear physics which are not part of the the traditional framework of the meson-nucleon description of nuclei. Many of these phenomena are related to high nuclear densities and the role of color in nucleonic interactions. Quantum fluctuations in the spatial separation between nucleons may lead to local high density configurations of cold nuclear matter in nuclei, up to four times larger than typical nuclear densities. We argue here that experiments utilizing the higher energies available upon completion of the Jefferson Laboratory energy upgrade will be able to probe the quark-gluon structure of such high density configurations and therefore elucidate the fundamental nature of nuclear matter. We review three key experimental programs: quasi-elastic electro-disintegration of light nuclei, deep inelastic scattering from nuclei at $x>1$, and the measurement of tagged structure functions. These interrelated programs are all aimed at the exploration of the quark structure of high density nuclear configurations. The study of the QCD dynamics of elementary hard processes is another important research direction and nuclei provide a unique avenue to explore these dynamics. We argue that the use of nuclear targets and large values of momentum transfer at would allow us to determine whether the physics of the nucleon form factors is dominated by spatially small configurations of three quarks., Comment: 52 pages IOP style LaTex file and 20 eps figures

Published
2002
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9. Neutron structure function and inclusive DIS from H-3 and He-3 targets at large Bjorken-x

Author

Sargsian, M. M., Simula, S., and Strikman, M. I.

Subjects
Nuclear Theory, High Energy Physics - Phenomenology
Abstract

A detailed study of inclusive deep inelastic scattering from mirror A = 3 nuclei at large values of Bjorken-x is presented. The main purpose is to estimate the theoretical uncertainties on the extraction of F2n from such measurements. Within the convolution approach we confirm the cancellation of nuclear effects at the level of ~1 % for x < 0.75 in overall agreement with previous findings. However, within models in which modifications of the bound nucleon structure functions are accounted for to describe the EMC effect in nuclei, we find that the nuclear effects may be canceled at a level of ~ 3 % only, leading to an accuracy of ~ 12 % in the extraction of F2n / F2p at x ~ 0.7 - 0.8. Another consequence of bound nucleon modifications is that the iteration procedure does not improve the accuracy of the extraction of F2n / F2p., Comment: Proc. of the IX International Conference on the Structure of Baryons, Jefferson Lab, March 3-8, 2002

Published
2002
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10. Neutron structure function and inclusive DIS from H-3 and He-3 at large Bjorken-x

Author

Sargsian, M. M., Simula, S., and Strikman, M. I.

Subjects
Nuclear Theory, High Energy Physics - Phenomenology
Abstract

A detailed study of inclusive deep inelastic scattering (DIS) from mirror A = 3 nuclei at large values of the Bjorken variable x is presented. The main purpose is to estimate the theoretical uncertainties on the extraction of the neutron DIS structure function from such nuclear measurements. On one hand, within models in which no modification of the bound nucleon structure functions is taken into account, we have investigated the possible uncertainties arising from: i) charge symmetry breaking terms in the nucleon-nucleon interaction, ii) finite Q**2 effects neglected in the Bjorken limit, iii) the role of different prescriptions for the nucleon Spectral Function normalization providing baryon number conservation, and iv) the differences between the virtual nucleon and light cone formalisms. Although these effects have been not yet considered in existing analyses, our conclusion is that all these effects cancel at the level of ~ 1% for x < 0.75 in overall agreement with previous findings. On the other hand we have considered several models in which the modification of the bound nucleon structure functions is accounted for to describe the EMC effect in DIS scattering from nuclei. It turns out that within these models the cancellation of nuclear effects is expected to occur only at a level of ~ 3%, leading to an accuracy of ~ 12 % in the extraction of the neutron to proton structure function ratio at x ~ 0.7 -0.8$. Another consequence of considering a broad range of models of the EMC effect is that the previously suggested iteration procedure does not improve the accuracy of the extraction of the neutron to proton structure function ratio., Comment: revised version to appear in Phys. Rev. C; main modifications in Section 4; no change in the conclusions

Published
2001
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11. On the Possibility to Study Color Transparency in the Large Momentum Transfer Exclusive $d(p,2p)n$ Reaction

Author

Frankfurt, L. L., Piasetzky, E., Sargsian, M. M., and Strikman, M. I.

Subjects
High Energy Physics - Phenomenology
Abstract

The deuteron disintegration at high energies and large angles in the $d(p,2p)n$ reaction, is calculated in kinematical conditions where the dominant contributions are due to soft rescatterings of the initial and final nucleons, which accompany the hard $pp$ reaction. The eikonal approximation, which accounts for relativistic kinematics as dictated by Feynman diagrams, reveals the important role played by the initial and final state interactions in the angular and momentum dependences of the differential cross section. Based on these results, we propose a new and effective test, at moderate energies, of the physics relevant for the color transparency phenomenon in hadron-initiated exclusive hard processes., Comment: 33 pages Latex file, 12 eps figures, uses epsfig.sty

Published
1996
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12. Feynman Graphs and Generalized Eikonal Approach to High Energy Knock-Out Processes

Author

Frankfurt, L. L., Sargsian, M. M., and Strikman, M. I.

Subjects
Nuclear Theory
Abstract

The cross section of hard semi-exclusive $A(e,e'N)(A-1)$ reactions for fixed missing energy and momentum is calculated within the eikonal approximation. Relativistic dynamics and kinematics of high energy processes are unambiguously accounted for by using the analysis of appropriate Feynman diagrams. A significant dependence of the final state interactions on the missing energy is found, which is important for interpretation of forthcoming color transparency experiments. A new, more stringent kinematic restriction on the region where the contribution of short-range nucleon correlations is enhanced in semi-exclusive knock-out processes is derived. It is also demonstrated that the use of light-cone variables leads to a considerable simplification of the description of high-energy knock-out reactions., Comment: 24 pages, LaTex, two Latex and two ps figures, uses FEYNMAN.tex and psfig.sty. Revisied version to appear in Phys. Rev. C

Published
1996
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13. Determination of the beam-spin asymmetry of deuteron photodisintegration in the energy region E-gamma=1.1-2.3 GeV

Author

Zachariou, Nicholas, Ilieva, Y., Berman, B. L., Ivanov, N. Ya., Sargsian, M. M., Avakian, R., Feldman, G., Nadel-Turonski, P., Adhikari, K. P., Adikaram, D., Anderson, M. D., Pereira, S. Anefalos, Avakian, H., Badui, R. A., Baltzell, N. A., Battaglieri, M., Baturin, V., Bedlinskiy, I., Biselli, A. S., Briscoe, W. J., Brooks, W. K., Burkert, V. D., Cao, T., Carman, D. S., Celentano, A., Chandavar, S., Charles, G., Colaneri, L., Cole, P. L., Compton, N., Contalbrigo, M., Cortes, O., Crede, V., D'Angelo, A., De Vita, R., De Sanctis, E., Deur, A., Djalali, C., Dupre, R., Egiyan, H., El Alaoui, A., El Fassi, L., Elouadrhiri, L., Fedotov, G., Fegan, S., Filippi, A., Fleming, J. A., Smith, Gary, Watts, D., and Zana, L.

Subjects
STRING MODEL, QUANTUM CHROMODYNAMICS, CLAS, 2-BODY PHOTODISINTEGRATION, PHOTOPRODUCTION, Physics::Accelerator Physics, High Energy Physics::Experiment, PROTON ELASTIC-SCATTERING, Nuclear Experiment, CROSS-SECTION, HARD PHOTODISINTEGRATION, LINEARLY POLARIZED PHOTONS, DISINTEGRATION
Abstract

The beam-spin asymmetry, Sigma, for the reaction gamma d -> pn has been measured using the CEBAF Large Acceptance Spectrometer (CLAS) at the Thomas Jefferson National Accelerator Facility (JLab) for six photon-energy bins, between 1.1 and 2.3 GeV, and proton angles in the center-of-mass frame, theta(c.m.), between 25 degrees and 160 degrees. These are the first measurements of beam-spin asymmetries at theta(c.m.) = 90. for photon-beam energies above 1.6 GeV, and the first measurements for angles other than theta(c.m.) = 90 degrees. The angular and energy dependence of Sigma is expected to aid in the development of QCD-based models to understand the mechanisms of deuteron photodisintegration in the transition region between hadronic and partonic degrees of freedom, where both effective field theories and perturbative QCD cannot make reliable predictions.

Published
2015

14. Determination of the beam-spin asymmetry of deuteron photodisintegration in the energy region Eγ=1.1–2.3 GeV

Author

Zachariou, N., Ilieva, Y., Berman, B. L., Ivanov, N. Ya., Sargsian, M. M., Avakian, R., Feldman, G., Nadel-Turonski, P., Adhikari, K. P., Adikaram, D., Anderson, M. D., Pereira, S. Anefalos, Avakian, H., Badui, R. A., Baltzell, N. A., Battaglieri, M., Baturin, V., Bedlinskiy, I., Biselli, A. S., Briscoe, W. J., Brooks, W. K., Burkert, V. D., Cao, T., Carman, D. S., Celentano, A., Chandavar, S., Charles, G., Colaneri, L., Cole, P. L., Compton, N., Contalbrigo, M., Cortes, O., Crede, V., D'Angelo, A., De Vita, R., De Sanctis, E., Deur, A., Djalali, C., Dupre, R., Egiyan, H., Alaoui, A. El, Fassi, L. El, Elouadrhiri, L., Fedotov, G., Fegan, S., Filippi, A., Fleming, J. A., Forest, T. A., Fradi, A., Gevorgyan, N., Ghandilyan, Y., Gilfoyle, G. P., Giovanetti, K. L., Girod, F. X., Glazier, D. I., Golovatch, E., Gothe, R. W., Griffioen, K. A., Guidal, M., Hafidi, K., Hanretty, C., Harrison, N., Hattawy, M., Hicks, K., Ho, D., Holtrop, M., Hughes, S. M., Ireland, D. G., Ishkhanov, B. S., Isupov, E. L., Jiang, H., Jo, H. S., Joo, K., Keller, D., Khachatryan, G., Khandaker, M., Kim, A., Kim, W., Klein, F. J., Kubarovsky, V., Lenisa, P., Livingston, K., Lu, H. Y., MacGregor, I. J. D., Markov, N., Mattione, P. T., Mckinnon, B., Mineeva, T., Mirazita, M., Mokeeev, V. I., Montgomery, R. A., Moutarde, H., Muñoz Camacho, C., Net, L. A., Niccolai, S., Niculescu, G., Niculescu, I., Osipenko, M., Ostrovidov, A. I., Park, K., Pasyuk, E., Phelps, W., Phillips, J. J., Pisano, S., Pogorelko, O., Pozdniakov, S., Price, J. W., Procureur, S., Prok, Y., Protopopescu, D., Puckett, A. J. R., Ripani, M., Rizzo, A., Rosner, G., Rossi, P., Roy, Pascal, Sabatié, F., Salgado, C., Schott, D., Schumacher, R. A., Seder, E., Senderovich, I., Sharabian, Y. G., Skorodumina, Iu., Smith, G. D., Sober, D. I., Sokhan, D., Sparveris, N., Stepanyan, S., Strauch, S., Sytnik, V., Taiuti, M., Tian, Ye, Ungaro, M., Voskanyan, H., Voutier, E., Walford, N. K., Watts, D., Wei, X., Wood, M. H., Zana, L., Zhang, J., Zhao, Z. W., Zonta, I., Institut de Physique Nucléaire d'Orsay (IPNO), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Institut de Recherches sur les lois Fondamentales de l'Univers (IRFU), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, CLAS, and Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)

Subjects
QUANTUM CHROMODYNAMICS, 2-BODY PHOTODISINTEGRATION, LINEARLY POLARIZED PHOTONS, PROTON ELASTIC-SCATTERING, CROSS-SECTION, HARD PHOTODISINTEGRATION, STRING MODEL, CLAS, PHOTOPRODUCTION, DISINTEGRATION, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], NO, Physics::Accelerator Physics, High Energy Physics::Experiment, Nuclear Experiment
Abstract

The beam-spin asymmetry, $\Sigma$, for the reaction $\gamma d\rightarrow pn$ has been measured using the CEBAF Large Acceptance Spectrometer (CLAS) at the Thomas Jefferson National Accelerator Facility (JLab) for six photon-energy bins between 1.1 and 2.3 GeV, and proton angles in the center-of-mass frame, $\theta_{c.m.}$, between $25^\circ$ and $160^\circ$. These are the first measurements of beam-spin asymmetries at $\theta_{c.m.}=90^\circ$ for photon-beam energies above 1.6 GeV, and the first measurements for angles other than $\theta_{c.m.}=90^\circ$. The angular and energy dependence of $\Sigma$ is expected to aid in the development of QCD-based models to understand the mechanisms of deuteron photodisintegration in the transition region between hadronic and partonic degrees of freedom, where both effective field theories and perturbative QCD cannot make reliable predictions., Comment: 18 pages

Published
2015

15. Measurement of the Neutron Electric to Magnetic Form Factor Ratio at Q2=1.58 GeV2 Using the Reaction He−→3(e⃗ ,e′n)pp

Author

Schlimme, B.S., Achenbach, P., Ayerbe Gayoso, C. A., Bernauer, J. C., Böhm, R., Bosnar, D., Challand, T., Distler, M.O., Doria, L., Fellenberger, F., Fonvieille, H., Gómez Rodríguez, M., Grabmayr, P., Hehl, T., Heil, W., Kiselev, D., Krimmer, J., Makek, M., Merkel, H., Middleton, D. G., Müller, U., Nungesser, L., Ott B., A., Pochodzalla, J., Potokar, M., Sánchez Majos, S., Sargsian M., M., Sick, I., Širca, S., Weinriefer, M., Wendel, M., Yoon, J., Institut für Kernphysik, Johannes Gutenberg - Universität Mainz = Johannes Gutenberg University (JGU), Department of Physics [Zagreb], Faculty of Science [Zagreb], University of Zagreb-University of Zagreb, Department of Physics, University of Basel (Unibas), Laboratoire de Physique Corpusculaire - Clermont-Ferrand (LPC), Université Blaise Pascal - Clermont-Ferrand 2 (UBP)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Physikalisches Institut [Tübingen], Eberhard Karls Universität Tübingen = Eberhard Karls University of Tuebingen, Institut für Physik [Mainz], The Swiss Light Source (SLS) (SLS-PSI), Paul Scherrer Institute (PSI), Institut de Physique Nucléaire de Lyon (IPNL), Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Jozef Stefan Institute [Ljubljana] (IJS), Florida International University [Miami] (FIU), University of Ljubljana, Johannes Gutenberg - Universität Mainz (JGU), Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), and Université de Lyon-Université de Lyon-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)

Subjects
High Energy Physics::Experiment, Nuclear Experiment
Abstract

International audience; A measurement of beam helicity asymmetries in the reaction He−→3(e⃗ ,e′n)pp is performed at the Mainz Microtron in quasielastic kinematics to determine the electric to magnetic form factor ratio of the neutron GnE/GnM at a four-momentum transfer Q2=1.58 GeV2. Longitudinally polarized electrons are scattered on a highly polarized He3 gas target. The scattered electrons are detected with a high-resolution magnetic spectrometer, and the ejected neutrons are detected with a dedicated neutron detector composed of scintillator bars. To reduce systematic errors, data are taken for four different target polarization orientations allowing the determination of GnE/GnM from a double ratio. We find μnGnE/GnM=0.250±0.058(stat)±0.017(syst).

Published
2013

18. Measurement of the Neutron Electric to Magnetic Form Factor Ratio atQ2=1.58GeV2Using the ReactionHe→3(e→,e′n)pp

Author

Schlimme, B. S., primary, Achenbach, P., additional, Ayerbe Gayoso, C. A., additional, Bernauer, J. C., additional, Böhm, R., additional, Bosnar, D., additional, Challand, Th., additional, Distler, M. O., additional, Doria, L., additional, Fellenberger, F., additional, Fonvieille, H., additional, Gómez Rodríguez, M., additional, Grabmayr, P., additional, Hehl, T., additional, Heil, W., additional, Kiselev, D., additional, Krimmer, J., additional, Makek, M., additional, Merkel, H., additional, Middleton, D. G., additional, Müller, U., additional, Nungesser, L., additional, Ott, B. A., additional, Pochodzalla, J., additional, Potokar, M., additional, Sánchez Majos, S., additional, Sargsian, M. M., additional, Sick, I., additional, Širca, S., additional, Weinriefer, M., additional, Wendel, M., additional, and Yoon, C. J., additional

Published
2013
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20. Measurements of the Electric Form Factor of the Neutron up toQ2=3.4GeV2Using the Reaction3He→(e→,e′n)pp

Author

Riordan, S., primary, Abrahamyan, S., additional, Craver, B., additional, Kelleher, A., additional, Kolarkar, A., additional, Miller, J., additional, Cates, G. D., additional, Liyanage, N., additional, Wojtsekhowski, B., additional, Acha, A., additional, Allada, K., additional, Anderson, B., additional, Aniol, K. A., additional, Annand, J. R. M., additional, Arrington, J., additional, Averett, T., additional, Beck, A., additional, Bellis, M., additional, Boeglin, W., additional, Breuer, H., additional, Calarco, J. R., additional, Camsonne, A., additional, Chen, J. P., additional, Chudakov, E., additional, Coman, L., additional, Crowe, B., additional, Cusanno, F., additional, Day, D., additional, Degtyarenko, P., additional, Dolph, P. A. M., additional, Dutta, C., additional, Ferdi, C., additional, Fernández-Ramírez, C., additional, Feuerbach, R., additional, Fraile, L. M., additional, Franklin, G., additional, Frullani, S., additional, Fuchs, S., additional, Garibaldi, F., additional, Gevorgyan, N., additional, Gilman, R., additional, Glamazdin, A., additional, Gomez, J., additional, Grimm, K., additional, Hansen, J.-O., additional, Herraiz, J. L., additional, Higinbotham, D. W., additional, Holmes, R., additional, Holmstrom, T., additional, Howell, D., additional, de Jager, C. W., additional, Jiang, X., additional, Jones, M. K., additional, Katich, J., additional, Kaufman, L. J., additional, Khandaker, M., additional, Kelly, J. J., additional, Kiselev, D., additional, Korsch, W., additional, LeRose, J., additional, Lindgren, R., additional, Markowitz, P., additional, Margaziotis, D. J., additional, Beck, S. May-Tal, additional, Mayilyan, S., additional, McCormick, K., additional, Meziani, Z.-E., additional, Michaels, R., additional, Moffit, B., additional, Nanda, S., additional, Nelyubin, V., additional, Ngo, T., additional, Nikolenko, D. M., additional, Norum, B., additional, Pentchev, L., additional, Perdrisat, C. F., additional, Piasetzky, E., additional, Pomatsalyuk, R., additional, Protopopescu, D., additional, Puckett, A. J. R., additional, Punjabi, V. A., additional, Qian, X., additional, Qiang, Y., additional, Quinn, B., additional, Rachek, I., additional, Ransome, R. D., additional, Reimer, P. E., additional, Reitz, B., additional, Roche, J., additional, Ron, G., additional, Rondon, O., additional, Rosner, G., additional, Saha, A., additional, Sargsian, M. M., additional, Sawatzky, B., additional, Segal, J., additional, Shabestari, M., additional, Shahinyan, A., additional, Shestakov, Yu., additional, Singh, J., additional, Širca, S., additional, Souder, P., additional, Stepanyan, S., additional, Stibunov, V., additional, Sulkosky, V., additional, Tajima, S., additional, Tobias, W. A., additional, Udias, J. M., additional, Urciuoli, G. M., additional, Vlahovic, B., additional, Voskanyan, H., additional, Wang, K., additional, Wesselmann, F. R., additional, Vignote, J. R., additional, Wood, S. A., additional, Wright, J., additional, Yao, H., additional, and Zhu, X., additional

Published
2010
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21. Measurement of Two- and Three-Nucleon Short-Range Correlation Probabilities in Nuclei

Author

Egiyan, K. S., primary, Dashyan, N. B., additional, Sargsian, M. M., additional, Strikman, M. I., additional, Weinstein, L. B., additional, Adams, G., additional, Ambrozewicz, P., additional, Anghinolfi, M., additional, Asavapibhop, B., additional, Asryan, G., additional, Avakian, H., additional, Baghdasaryan, H., additional, Baillie, N., additional, Ball, J. P., additional, Baltzell, N. A., additional, Batourine, V., additional, Battaglieri, M., additional, Bedlinskiy, I., additional, Bektasoglu, M., additional, Bellis, M., additional, Benmouna, N., additional, Biselli, A. S., additional, Bonner, B. E., additional, Bouchigny, S., additional, Boiarinov, S., additional, Bradford, R., additional, Branford, D., additional, Brooks, W. K., additional, Bültmann, S., additional, Burkert, V. D., additional, Bultuceanu, C., additional, Calarco, J. R., additional, Careccia, S. L., additional, Carman, D. S., additional, Carnahan, B., additional, Chen, S., additional, Cole, P. L., additional, Coltharp, P., additional, Corvisiero, P., additional, Crabb, D., additional, Crannell, H., additional, Cummings, J. P., additional, Sanctis, E. De, additional, DeVita, R., additional, Degtyarenko, P. V., additional, Denizli, H., additional, Dennis, L., additional, Dharmawardane, K. V., additional, Djalali, C., additional, Dodge, G. E., additional, Donnelly, J., additional, Doughty, D., additional, Dragovitsch, P., additional, Dugger, M., additional, Dytman, S., additional, Dzyubak, O. P., additional, Egiyan, H., additional, Elouadrhiri, L., additional, Empl, A., additional, Eugenio, P., additional, Fatemi, R., additional, Fedotov, G., additional, Feuerbach, R. J., additional, Forest, T. A., additional, Funsten, H., additional, Gavalian, G., additional, Gevorgyan, N. G., additional, Gilfoyle, G. P., additional, Giovanetti, K. L., additional, Girod, F. X., additional, Goetz, J. T., additional, Golovatch, E., additional, Gothe, R. W., additional, Griffioen, K. A., additional, Guidal, M., additional, Guillo, M., additional, Guler, N., additional, Guo, L., additional, Gyurjyan, V., additional, Hadjidakis, C., additional, Hardie, J., additional, Hersman, F. W., additional, Hicks, K., additional, Hleiqawi, I., additional, Holtrop, M., additional, Hu, J., additional, Huertas, M., additional, Hyde-Wright, C. E., additional, Ilieva, Y., additional, Ireland, D. G., additional, Ishkhanov, B. S., additional, Ito, M. M., additional, Jenkins, D., additional, Jo, H. S., additional, Joo, K., additional, Juengst, H. G., additional, Kellie, J. D., additional, Khandaker, M., additional, Kim, K. Y., additional, Kim, K., additional, Kim, W., additional, Klein, A., additional, Klein, F. J., additional, Klimenko, A., additional, Klusman, M., additional, Kramer, L. H., additional, Kubarovsky, V., additional, Kuhn, J., additional, Kuhn, S. E., additional, Kuleshov, S., additional, Lachniet, J., additional, Laget, J. M., additional, Langheinrich, J., additional, Lawrence, D., additional, Lee, T., additional, Livingston, K., additional, Maximon, L. C., additional, McAleer, S., additional, McKinnon, B., additional, McNabb, J. W. C., additional, Mecking, B. A., additional, Mestayer, M. D., additional, Meyer, C. A., additional, Mibe, T., additional, Mikhailov, K., additional, Minehart, R., additional, Mirazita, M., additional, Miskimen, R., additional, Mokeev, V., additional, Morrow, S. A., additional, Mueller, J., additional, Mutchler, G. S., additional, Nadel-Turonski, P., additional, Napolitano, J., additional, Nasseripour, R., additional, Niccolai, S., additional, Niculescu, G., additional, Niculescu, I., additional, Niczyporuk, B. B., additional, Niyazov, R. A., additional, O’Rielly, G. V., additional, Osipenko, M., additional, Ostrovidov, A. I., additional, Park, K., additional, Pasyuk, E., additional, Peterson, C., additional, Pierce, J., additional, Pivnyuk, N., additional, Pocanic, D., additional, Pogorelko, O., additional, Polli, E., additional, Pozdniakov, S., additional, Preedom, B. M., additional, Price, J. W., additional, Prok, Y., additional, Protopopescu, D., additional, Qin, L. M., additional, Raue, B. A., additional, Riccardi, G., additional, Ricco, G., additional, Ripani, M., additional, Ritchie, B. G., additional, Ronchetti, F., additional, Rosner, G., additional, Rossi, P., additional, Rowntree, D., additional, Rubin, P. D., additional, Sabatié, F., additional, Salgado, C., additional, Santoro, J. P., additional, Sapunenko, V., additional, Schumacher, R. A., additional, Serov, V. S., additional, Sharabian, Y. G., additional, Shaw, J., additional, Smith, E. S., additional, Smith, L. C., additional, Sober, D. I., additional, Stavinsky, A., additional, Stepanyan, S., additional, Stokes, B. E., additional, Stoler, P., additional, Strauch, S., additional, Suleiman, R., additional, Taiuti, M., additional, Taylor, S., additional, Tedeschi, D. J., additional, Thompson, R., additional, Tkabladze, A., additional, Tkachenko, S., additional, Todor, L., additional, Tur, C., additional, Ungaro, M., additional, Vineyard, M. F., additional, Vlassov, A. V., additional, Weygand, D. P., additional, Williams, M., additional, Wolin, E., additional, Wood, M. H., additional, Yegneswaran, A., additional, Yun, J., additional, Zana, L., additional, and Zhang, J., additional

Published
2006
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24. Hadrons in the nuclear medium

Author

Sargsian, M M, primary, Arrington, J, additional, Bertozzi, W, additional, Boeglin, W, additional, Carlson, C E, additional, Day, D B, additional, Frankfurt, L L, additional, Egiyan, K, additional, Ent, R, additional, Gilad, S, additional, Griffioen, K, additional, Higinbotham, D W, additional, Kuhn, S, additional, Melnitchouk, W, additional, Miller, G A, additional, Piasetzky, E, additional, Stepanyan, S, additional, Strikman, M I, additional, and Weinstein, L B, additional

Published
2003
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30. Scaling and resonances in elementary K+Λ photoproduction.

Author

Schumacher, R. A. and Sargsian, M. M.

Subjects
*SCALING laws (Nuclear physics), *MESON resonance, *ANGULAR momentum (Nuclear physics), *MESONS, *KINEMATICS, *HADRONS
Abstract

Recent cross-section data for the reaction γ+p→K++Λ are examined for evidence of scaling in both the low-t Regge domain and in the high-√s and -t domain where constituent counting may apply. It is shown that the reaction does scale in both regimes. At large center-of-mass angles, s-7 scaling appears to hold at essentially all -t but with angle-dependent oscillations. The scaled data show particularly strong evidence for s-channel resonances for -t below 2 GeV2 and for W below about 2.3 GeV. The dominant contributions are consistent with an N*S11 resonance at 1690 MeV, a P13 resonance at 1920 MeV, and a D13 resonance at 2100 MeV, which interfere to give the observed strong angular dependence. [ABSTRACT FROM AUTHOR]

Published
2011
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31. Study of color transparency in two-body breakup processes

Author

Chen, Jian-Ping, Chudakov, E., Jager, C. W., Gomez, J., Hansen, O., Higinbotham, D. W., Jones, M., Lerose, J., Michaels, R., Reitz, B., Saha, A., Wojtsekhowski, B., Aniol, K., Epstein, M., Margaziotis, D., Bertozzi, W., Gayou, O., Gilad, S., Rvachev, M., Suleiman, R., Griffioen, K. A., Boeglin, W., Markowitz, P., Sargsian, M. M., Cusanno, F., Frullani, S., Garibaldi, F., Iodice, M., Urciuoli, G. M., Batigne, G., Furget, C., Guillon, B., Kox, S., Mougey, J., Moussiegt, P., Penal-Nottaris, E., Real, J. S., Voutier, E., Hyde, Charles Earl, Ulmer, P. E., Weinstein, L., Benmokhtar, F., Ronald Gilman, Glashausser, C., Jiang, X., Kumbartzki, G., Mccormick, K., Ransome, R., Chang, G., Calarco, J., Lindgren, R., Liyanage, N., Strikman, M., Sarty, A. J., Bertin, P., and Egiyan, K.

32. The Present and Future of QCD

Author

Achenbach, P., Adhikari, D., Afanasev, A., Afzal, F., Aidala, C. A., Al-Bataineh, A., Almaalol, D. K., Amaryan, M., Androić, D., Armstrong, W. R., Arratia, M., Arrington, J., Asaturyan, A., Aschenauer, E. C., Atac, H., Avakian, H., Averett, T., Ayerbe Gayoso, C., Bai, X., Barish, K. N., Barnea, N., Basar, G., Battaglieri, M., Baty, A. A., Bautista, I., Bazilevsky, A., Beattie, C., Behera, S. C., Bellini, V., Bellwied, R., Benesch, J. F., Benmokhtar, F., Bernardes, C. A., Bernauer, J. C., Bhatt, H., Bhatta, S., Boer, M., Boettcher, T. J., Bogacz, S. A., Bossi, H. J., Brandenburg, J. D., Brash, E. J., Briceño, R. A., Briscoe, W. J., Brodsky, S. J., Brown, D. A., Burkert, V. D., Caines, H., Cali, I. A., Camsonne, A., Carman, D. S., Caylor, J., Cerci, S., Llatas, M. Chamizo, Chatterjee, S., Chen, J. P., Chen, Y., Chen, Y. -C, Chien, Y. -T, Chou, P. -C, Chu, X., Chudakov, E., Cline, E., Cloët, I. C., Cole, P. L., Connors, M. E., Constantinou, M., Cosyn, W., Dusa, S. Covrig, Cruz-Torres, R., D Alesio, U., Da Silva, C., Davoudi, Z., Dean, C. T., Dean, D. J., Demarteau, M., Deshpande, A., Detmold, W., Deur, A., Devkota, B. R., Dhital, S., Diefenthaler, M., Dobbs, S., Döring, M., Dong, X., Dotel, R., Dow, K. A., Downie, E. J., Drachenberg, J. L., Dumitru, A., Dunlop, J. C., Dupre, R., Durham, J. M., Dutta, D., Edwards, R. G., Ehlers, R. J., El Fassi, L., Elaasar, M., Elouadrhiri, L., Engelhardt, M., Ent, R., Esumi, S., Evdokimov, O., Eyser, O., Fanelli, C., Fatemi, R., Fernando, I. P., Flor, F. A., Fomin, N., Frawley, A. D., Frederico, T., Fries, R. J., Gal, C., Gamage, B. R., Gamberg, L., Gao, H., Gaskell, D., Geurts, F., Ghandilyan, Y., Ghimire, N., Gilman, R., Gleason, C., Gnanvo, K., Gothe, R. W., Greene, S. V., Grießhammer, H. W., Grossberndt, S. K., Grube, B., Hackett, D. C., Hague, T. J., Hakobyan, H., Hansen, J. -O, Hatta, Y., Hattawy, M., Havener, L. B., Hen, O., Henry, W., Higinbotham, D. W., Hobbs, T. J., Hodges, A. M., Holmstrom, T., Hong, B., Horn, T., Howell, C. R., Huang, H. Z., Huang, M., Huang, S., Huber, G. M., Hyde, C. E., Isupov, E. L., Jacobs, P. M., Jalilian-Marian, J., Jentsch, A., Jheng, H., Ji, C. -R, Ji, X., Jia, J., Jones, D. C., Jones, M. K., Kalantarians, N., Kalicy, G., Kang, Z. B., Karthein, J. M., Keller, D., Keppel, C., Khachatryan, V., Kharzeev, D. E., Kim, H., Kim, M., Kim, Y., King, P. M., Kinney, E., Klein, S. R., Ko, H. S., Koch, V., Kohl, M., Kovchegov, Y. V., Krintiras, G. K., Kubarovsky, V., Kuhn, S. E., Kumar, K. S., Kutz, T., Lajoie, J. G., Lauret, J., Lavrukhin, I., Lawrence, D., Lee, J. H., Lee, K., Lee, S., Lee, Y. -J, Li, S., Li, W., Li, Xiaqing, Li, Xuan, Liao, J., Lin, H. -W, Lisa, M. A., Liu, K. -F, Liu, M. X., Liu, T., Liuti, S., Liyanage, N., Llope, W. J., Loizides, C., Longo, R., Lorenzon, W., Lunkenheimer, S., Luo, X., Ma, R., Mckinnon, B., Meekins, D. G., Mehtar-Tani, Y., Melnitchouk, W., Metz, A., Meyer, C. A., Meziani, Z. -E, Michaels, R., Michel, J. K. L., Milner, R. G., Mkrtchyan, H., Mohanmurthy, P., Mohanty, B., Mokeev, V. I., Moon, D. H., Mooney, I. A., Morningstar, C., Morrison, D. P., Müller, B., Mukherjee, S., Mulligan, J., Munoz Camacho, C., Murillo Quijada, J. A., Murray, M. J., Nadeeshani, S. A., Nadel-Turonski, P., Nam, J. D., Nattrass, C. E., Nijs, G., Noronha, J., Noronha-Hostler, J., Novitzky, N., Nycz, M., Olness, F. I., Osborn, J. D., Pak, R., Pandey, B., Paolone, M., Papandreou, Z., Paquet, J. -F, Park, S., Paschke, K. D., Pasquini, B., Pasyuk, E., Patel, T., Patton, A., Paudel, C., Peng, C., Peng, J. C., Da Costa, H. Pereira, Perepelitsa, D. V., Peters, M. J., Petreczky, P., Pisarski, R. D., Pitonyak, D., Ploskon, M. A., Posik, M., Poudel, J., Pradhan, R., Prokudin, A., Pruneau, C. A., Puckett, A. J. R., Pujahari, P., Putschke, J., Pybus, J. R., Qiu, J. -W, Rajagopal, K., Ratti, C., Read, K. F., Reed, R., Richards, D. 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Subjects
Nuclear Theory, nucl-th, hep-ex, FOS: Physical sciences, hep-ph, nucl-ex, High Energy Physics - Experiment, Nuclear Theory (nucl-th), High Energy Physics - Phenomenology, High Energy Physics - Experiment (hep-ex), High Energy Physics - Phenomenology (hep-ph), Nuclear Physics - Theory, Nuclear Physics - Experiment, Nuclear Experiment (nucl-ex), Nuclear Experiment, Particle Physics - Experiment, Particle Physics - Phenomenology
Abstract

This White Paper presents the community inputs and scientific conclusions from the Hot and Cold QCD Town Meeting that took place September 23-25, 2022 at MIT, as part of the Nuclear Science Advisory Committee (NSAC) 2023 Long Range Planning process. A total of 424 physicists registered for the meeting. The meeting highlighted progress in Quantum Chromodynamics (QCD) nuclear physics since the 2015 LRP (LRP15) and identified key questions and plausible paths to obtaining answers to those questions, defining priorities for our research over the coming decade. In defining the priority of outstanding physics opportunities for the future, both prospects for the short (~ 5 years) and longer term (5-10 years and beyond) are identified together with the facilities, personnel and other resources needed to maximize the discovery potential and maintain United States leadership in QCD physics worldwide. This White Paper is organized as follows: In the Executive Summary, we detail the Recommendations and Initiatives that were presented and discussed at the Town Meeting, and their supporting rationales. Section 2 highlights major progress and accomplishments of the past seven years. It is followed, in Section 3, by an overview of the physics opportunities for the immediate future, and in relation with the next QCD frontier: the EIC. Section 4 provides an overview of the physics motivations and goals associated with the EIC. Section 5 is devoted to the workforce development and support of diversity, equity and inclusion. This is followed by a dedicated section on computing in Section 6. Section 7 describes the national need for nuclear data science and the relevance to QCD research., Comment: QCD Town Meeting White Paper, as submitted to 2023 NSAC LRP committee on Feb. 28, 2023

33. Measurements of the electric form factor of the neutron up to Q2=3.4 GeV2 using the reaction 3He(e,e'n)pp.

Author

Riordan S, Abrahamyan S, Craver B, Kelleher A, Kolarkar A, Miller J, Cates GD, Liyanage N, Wojtsekhowski B, Acha A, Allada K, Anderson B, Aniol KA, Annand JR, Arrington J, Averett T, Beck A, Bellis M, Boeglin W, Breuer H, Calarco JR, Camsonne A, Chen JP, Chudakov E, Coman L, Crowe B, Cusanno F, Day D, Degtyarenko P, Dolph PA, Dutta C, Ferdi C, Fernández-Ramírez C, Feuerbach R, Fraile LM, Franklin G, Frullani S, Fuchs S, Garibaldi F, Gevorgyan N, Gilman R, Glamazdin A, Gomez J, Grimm K, Hansen JO, Herraiz JL, Higinbotham DW, Holmes R, Holmstrom T, Howell D, de Jager CW, Jiang X, Jones MK, Katich J, Kaufman LJ, Khandaker M, Kelly JJ, Kiselev D, Korsch W, LeRose J, Lindgren R, Markowitz P, Margaziotis DJ, Beck SM, Mayilyan S, McCormick K, Meziani ZE, Michaels R, Moffit B, Nanda S, Nelyubin V, Ngo T, Nikolenko DM, Norum B, Pentchev L, Perdrisat CF, Piasetzky E, Pomatsalyuk R, Protopopescu D, Puckett AJ, Punjabi VA, Qian X, Qiang Y, Quinn B, Rachek I, Ransome RD, Reimer PE, Reitz B, Roche J, Ron G, Rondon O, Rosner G, Saha A, Sargsian MM, Sawatzky B, Segal J, Shabestari M, Shahinyan A, Shestakov Y, Singh J, Sirca S, Souder P, Stepanyan S, Stibunov V, Sulkosky V, Tajima S, Tobias WA, Udias JM, Urciuoli GM, Vlahovic B, Voskanyan H, Wang K, Wesselmann FR, Vignote JR, Wood SA, Wright J, Yao H, and Zhu X

Abstract

The electric form factor of the neutron was determined from studies of the reaction 3He(e,e'n)pp in quasielastic kinematics in Hall A at Jefferson Lab. Longitudinally polarized electrons were scattered off a polarized target in which the nuclear polarization was oriented perpendicular to the momentum transfer. The scattered electrons were detected in a magnetic spectrometer in coincidence with neutrons that were registered in a large-solid-angle detector. More than doubling the Q2 range over which it is known, we find G(E)(n)=0.0236±0.0017(stat)±0.0026(syst), 0.0208±0.0024±0.0019, and 0.0147±0.0020±0.0014 for Q(2)=1.72, 2.48, and 3.41 GeV2, respectively.

Published
2010
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