Autor: Moch, M. - Prolib Integro

Skocz do pozycji: 1.

Tytuł:: Measurement of the electron structure function $F_{2}^{e}$ at LEP energies
Autorzy:: Fuster, J.
Zalewska, A.
Veloso, F.
Benvenuti, A.
Cavallo, F.
Pukhaeva, N.
Todorovova, S.
Petrolini, A.
Benekos, N.
Mazzucato, F.
Moenig, K.
Treille, D.
Begalli, M.
Rovelli, T.
Meroni, C.
Sokolov, A.
Abdallah, J.
Wicke, D.
Siebel, M.
Van Vulpen, I.
Spassov, T.
Zavrtanik, D.
Ferrer, A.
Szumlak, T.
Wickens, J.
Sander, C.
Jarry, P.
Muryn, B.
Borisov, G.
Crennell, D.
De Maria, N.
Tonazzo, A.
Barker, G. J.
Garcia, C.
Berat, C.
Mandl, F.
Amato, S.
Nikolenko, M.
Ferro, F.
Ruhlmann-Kleider, V.
Asman, B.
Lesiak, T.
Adzic, P.
Liebig, W.
Tobin, M.
Matorras, F.
Mazzucato, M.
Lyons, L.
Fernandez, J.
van Remortel, N.
Andreazza, A.
Tzamarias, S.
Katsoufis, E.
Ballestrero, A.
Flagmeyer, U.
Stugu, B.
Zupan, M.
Di Ciaccio, L.
Rivero, M.
Behrmann, A.
De Boer, W.
Contri, R.
Mulders, M.
Myklebust, T.
Bertrand, D.
Blom, M.
Augustin, J. E.
Jonsson, P.
Brenner, R.
Myatt, G.
Romero, A.
Ouraou, A.
Tortosa, P.
Della Ricca, G.
Oyanguren, A.
Kapusta, F.
da Silva, T.
Parkes, C.
Ellert, M.
Ryabtchikov, D.
Abreu, P.
Piotto, E.
Orava, R.
Vitale, L.
Zimin, N. I.
Drees, J.
Vrba, V.
Winter, M.
Lutz, P.
Kouznetsov, O.
Jackson, J. N.
Sosnowski, R.
Szczekowski, M.
Moa, T.
Arnoud, Y.
Mueller, U.
Smadja, G.
Krumstein, Z.
Bonesini, M.
Augustinus, A.
Camporesi, T.
Ben-Haim, E.
Johansson, E. K.
Jungermann, L.
Grosdidier, G.
Muenich, K.
Besancon, M.
Mariotti, C.
Ask, S.
Pimenta, M.
Salmi, L.
Anjos, N.
Boyko, I.
Renton, P.
Belous, K.
Chudoba, J.
Palacios, J. P.
Castro, N.
Allport, P. P.
Trochimczuk, M.
Moreno, S.
Sisakian, A.
Eigen, G.
Liko, D.
Bowcock, T. J. W.
Cuevas, J.
Haug, S.
Rodriguez, D.
Apel, W-D.
MacNaughton, J.
Ledroit, F.
Moraes, D.
Baroncelli, A.
De Clercq, C.
Buschmann, P.
Martinez-Rivero, C.
Tome, B.
Bambade, P.
Di Simone, A.
Polok, G.
Leinonen, L.
Carena, F.
Bouquet, B.
Booth, P. S. L.
Leder, G.
Elsing, M.
Holmgren, S-O.
Podobnik, T.
Yushchenko, O.
Stanitzki, M.
Kerzel, U.
Antilogus, P.
Uvarov, V.
Gavillet, Ph.
Cossutti, F.
Vilanova, D.
Lepeltier, V.
Poireau, V.
Pozdniakov, V.
Olshevski, A.
Botner, O.
Gomez-Ceballos, G.
Reid, D.
Mundim, L.
Albrecht, T.
Van Eldik, J.
Battaglia, M.
Haag, C.
de Paula, L.
Smirnova, O.
Margoni, M.
Papadopoulou, Th. D.
Chierici, R.
Marin, J-C.
Migliore, E.
Brunet, J. M.
Tkatchev, L.
Cieslik, K.
Mastroyiannopoulos, N.
Fokitis, E.
Maltezos, S.
Costa, M. J.
Katsanevas, S.
Pierre, F.
Bluj, M.
Malek, A.
Berggren, M.
Barbier, R.
D'Hondt, J.
Nawrocki, K.
Brodet, E.
Hedberg, V.
King, B. T.
Zintchenko, A.
Passon, O.
Buschbeck, B.
Nicolaidou, R.
Hauler, F.
Turluer, M-L.
Verzi, V.
Marechal, B.
Sopczak, A.
Richard, F.
Hallgren, A.
Fanourakis, G.
Pape, L.
Hennecke, M.
Radojicic, D.
Guy, J.
Parodi, F.
Washbrook, A. J.
Onofre, A.
Salt, J.
Adam, W.
Paganoni, M.
Baillon, P.
Loukas, D.
Tabarelli, T.
Marco, J.
Doroba, K.
Wilkinson, G.
Kucharczyk, M.
Gokieli, R.
Ronchese, P.
Nemecek, S.
Oblakowska-Mucha, A.
Verdier, P.
Nassiakou, M.
Valenti, G.
Kluit, P.
Passeri, A.
Markou, A.
Chapkin, M.
Foeth, H.
Gazis, E.
De Lotto, B.
Vegni, G.
Fulda-Quenzer, F.
Leitner, R.
Matteuzzi, C.
Hamilton, K.
Hamacher, K.
Weiser, C.
Jeans, D.
Cosme, G.
Bloch, D.
Pieri, L.
Ridky, M.
Amapane, N.
Murray, W.
Baubillier, M.
Kernel, G.
Szwed, Jerzy
Allmendinger, T.
Bruckman, P.
Perrotta, A.
Jarlskog, G.
Zhuravlov, V.
Mjoernmark, U.
Montenegro, J.
Ekelof, T.
Checchia, P.
Witek, M.
Sekulin, R.
Stocchi, A.
Tyapkin, I. A.
Piedra, J.
Mitaroff, W.
Chung, S. U.
Bracko, M.
Obraztsov, V.
Schwickerath, U.
Goncalves, P.
Parzefall, U.
Chliapnikov, P.
Marco, R.
Mc Nulty, R.
Espirito Santo, M. C.
Troncon, C.
Becks, K-H.
Osterberg, K.
Fassouliotis, D.
Collins, P.
Lamsa, J.
Pol, M. E.
Rebecchi, P.
Zalewski, P.
Roudeau, P.
Venus, W.
Da Silva, W.
Palka, H.
Savoy-Navarro, A.
Graziani, E.
Morettini, P.
Perepelitsa, V.
Grzelak, K.
Wahlen, H.
Bardin, D.
Kourkoumelis, C.
Moch, M.
Feindt, M.
Kjaer,N. J.
Lipniacka, A.
Golob, B.
Sadovsky, A.
Rehn, J.
Andringa, S.
Navarria, F.
De Min, A.
Strauss, J.
Besson, N.
VanDam, P.
Timmermans, J.
Charpentier, Ph.
Szeptycka, M.
Alemany-Fernandez, R.
Peralta, L.
Tegenfeldt, F.
Houlden, M. A.
Masik, J.
Hoffman, J.
Lopes, J. H.
Lemonne, J.
Travnicek, P.
Joram, C.
Monge, R.
Kersevan, B. P.
Tristram, G.
Boonekamp, M.
Gandelman, M.
Holt, P. J.
Amaldi, U.
Kokkinias, P.
Pullia, A.
Anashkin, E.
Lopez, J. M.
Reinhardt, R.
Canale, V.
Paiano, S.
Słomiński, Wojciech
De Angelis, A.
Calvi, M.
Opis:: The hadronic part of the electron structure function $F_{2}^{e}$ has been measured for the first time, using $e^{+}e^{-} $ data collected by the DELPHI experiment at LEP, at centre-of-mass energies of $\sqrt{s}$=91.2-209.5 GeV. The data analysis is simpler than that of the measurement of the photon structure function. The electron structure function $F_{2}^{e}$ data are compared to predictions of phenomenological models based on the photon structure function. It is shown that the contribution of large target photon virtualities is significant. The data presented can serve as a cross-check of the photon structure function $F_{2}^{\gamma}$ analyses and help in refining existing parameterisations.
Dostawca treści:: Repozytorium Uniwersytetu Jagiellońskiego

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Skocz do pozycji: 2.

Tytuł:: Snowmass 2021 whitepaper : proton structure at the precision frontier
Autorzy:: Candido, A.
Moch, S.
Amoroso, S.
Siódmok, Andrzej
Britzger, D.
Ubiali, M.
Hoeche, S.
Weber, J. H.
Huston, J.
Giuli, F.
Hentschinski, M.
Boughezal, R.
Lin, H.-W.
Hekhorn, F.
Malaescu, B.
Mistlberger, B.
Harland-Lang, L. A.
Jadach, S.
Carrazza, S.
Apyan, A.
Rabbertz, K.
Ball, R. D.
Klein, M.
Schnell, G.
Xie, K.
Buckley, A.
Huss, A.
Bissolotti, C.
Petriello, F.
Pires, J.
Thorne, R. S.
Hobbs, T. J.
Courtoy, A.
Whitehead, James
Nocera, E. R.
Cridge, T.
Sutton, M.
Chachamis, G.
Rojo, J.
Schwan, C.
Blümlein, J.
Guzzi, M. G.
Jalilian-Marian, J.
Loizides, C.
Royon, C.
Yuan, C. -P.
Soper, D. E.
Olness, F. I.
Cooper-Sarkar, A. M.
Gwenlan, C.
Vita, G.
Bozzi, G.
Zhou, B.
Armesto, N.
Cruz-Martinez, J. M.
Bertone, V.
Cerci, S.
Krintiras, G. K.
Magni, G.
Celiberto, F. G.
Nadolsky, P. M.
Opis:: An overwhelming number of theoretical predictions for hadron colliders require parton distribution functions (PDFs), which are an important ingredient of theory infrastructure for the next generation of high-energy experiments. This whitepaper summarizes the status and future prospects for determination of high-precision PDFs applicable in a wide range of energies and experiments, in particular in precision tests of the Standard Model and in new physics searches at the high-luminosity Large Hadron Collider and Electron–Ion Collider. We discuss the envisioned advancements in experimental measurements, QCD theory, global analysis methodology, and computing that are necessary to bring unpolarized PDFs in the nucleon to the N2LO and N3LO accuracy in the QCD coupling strength. Special attention is given to the new tasks that emerge in the era of the precision PDF analysis, such as those focusing on the robust control of systematic factors both in experimental measurements and theoretical computations. Various synergies between experimental and theoretical studies of the hadron structure are explored, including opportunities for studying PDFs for nuclear and meson targets, PDFs with electroweak contributions or dependence on the transverse momentum, for incisive comparisons between phenomenological models for the PDFs and computations on discrete lattice, and for cross-fertilization with machine learning/AI approaches.
Dostawca treści:: Repozytorium Uniwersytetu Jagiellońskiego

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Skocz do pozycji: 3.

Autorzy:: Solans, C.
Andre, K. D. J.
Spiesberger, H.
Cakir, O.
Denizli, H.
Cruz-Alaniz, E.
Ruan, X.
Camarda, S.
Olivier, G.
Luo, X.
Azuelos, G.
Lei, G.
Lappi, T.
Glover, N.
Zhang, J.
Flores-Sánchez, O.
Krelina, M.
Gonzalez-Sprinberg, G. A.
Nowakowski, M.
Yock, P.
Hessler, J.
Xiaohao, C.
Bertolucci, S.
Coleppa, B.
Jana, S.
Tudora, A.
Alekhin, S.
Yamaguchi, Y.
Turk Cakir, I.
Raicevic, N.
Pan, R.
Morreale, A.
Sinha, N.
Shipman, N.
Olry, G.
Tommasini, D.
Perez-Segurana, G.
Giuli, F.
Gehrmann-De Ridder, A.
Sahin, M.
Harland-Lang, L.
Jansova, M.
Godbole, R. M.
Lobodzinska, E.
Zomer, F.
Behnke, O.
Salgado, C. A.
Pietralla, N.
Granados, E.
Hayden, D.
Apsimon, R.
Khalek, R. A.
Martens, A.
Calıskan, A.
Li, X.
Wei, H.
Korostelev, M.
Kaabi, W.
Laycock, P.
Han, C. C.
Hesari, H.
Stanyard, J.
Rosado, A.
Smith, S.
Russenschuck, S.
Gunaydin, Y. O.
Mitra, M.
Daly, E.
Angal-Kalinin, D.
Trbojevic, D.
Mäntysaari, H.
Kretzschmar, J.
Liuti, S.
Newman, P.
Ratoff, P.
Moretti, S.
Catalan-Lasheras, N. C.
Corsini, R.
Poelker, M.
Litvinenko, V.
Wang, B.
Pires, J.
Paukkunen, H.
Zhang, R.
Armbruster, A.
Gilbert, A.
de Blas, J.
Sekine, T.
Liu, Y.
Sampayo, O. A.
Zhang, Z.
Wollmann, D.
Pire, B.
Nissen, E. A.
Kulipanov, G.
Wang, K.
Karadeniz, H.
Das, A.
Rezaeian, A. H.
Cooper-Sarkar, A.
Gehrmann, T.
Bailey, I.
Tsurin, I.
Kalinin, D. A.
Duarte, L.
Cormier, E.
Valloni, A.
Tanaka, M.
Bordry, F.
Auchmann, B.
Wallon, S.
Schenke, B.
Nergiz, Z.
Brüning, O.
Gerigk, F.
Słomiński, Wojciech
Tywoniuk, K.
Dutta, S.
Mohammadi Najafabadi, M.
Bogacz, A.
Huss, A.
Senol, A.
Nadolsky, P.
Köksal, M.
Osborne, J. A.
Rashed, A.
Aperio Bella, L.
Mondal, S.
Tapia-Takaki, D.
Bracinik, J.
Apolinario, L.
Latina, A.
Cassou, K.
Militsyn, B.
Yue, C. X.
Olness, F.
Zurita, P.
Queiroz, F. S.
Haug, F.
Cepila, J.
Repond, J.
Cetinkaya, V.
Raut, D.
Yang, H.
Honorato, C. G.
Kocak, F.
Hoffstaetter, G. H.
Stasto, A.
Eichhorn, R.
Trott, M.
Shang, L.
Peinaud, Y.
Klein, U.
Deshpande, K. S.
Satendra, K.
Marhauser, F.
Liu, M.
Eskola, K. J.
Schulte, D.
Patra, M.
Liang, H.
Balli, F.
Bruni, C.
Hug, F.
Dassa, L.
Kostka, P.
Holzer, B.
Levitchev, E.
Apyan, A.
Starostenko, A.
Gonçalves, V.
Hod, N.
Dainton, J.
Kado, M.
Li, R.
Strikman, M.
Brodsky, S. J.
Goddard, B.
Liu, T.
Satyanarayan, N.
Wang, X.
Gaddi, A.
Perrot, L.
Hutton, A.
Kumar, M.
Fischer, O.
Zhang, C.
Pellegrini, D.
Rahaman, R.
Szymanowski, L.
Marquet, C.
Currie, J.
Sutton, M.
Bousson, S.
Milhano, J. G.
Tasci, A. T.
Kawaguchi, S.
McFayden, J.
Hounsell, B.
Hernandez-Sanchez, J.
Allport, P. P.
Backovic, S.
Okada, N.
Tomas-Garcia, R.
Welsch, C.
Willering, G.
Britzger, D.
Agostini, P.
Tapan, I.
Verney, D.
Grassellino, A.
Aulenbacher, K.
Niehues, J.
Bernauer, J.
Pownall, G.
Yilmaz, A.
Ma, W.
Efremov, A. V.
Schwanenberger, C.
Biswal, S. S.
Rai, S. K.
Williams, P. H.
Ozansoy, A.
Grames, J.
Setiniyaz, S.
Jensen, E.
Rabbertz, K.
Delle Rose, L.
Bouzas, A. O.
Andari, N.
Burkhardt, H.
Larios, F.
Benedikt, M.
Das, S. P.
Ben-Zvi, I.
Longuevergne, D.
Levy, A.
Caldwell, A.
Parker, B.
Meot, F.
Stuart, M. J.
Zadeh, S. G.
Goyal, A.
Helenius, I.
Raychaudhuri, S.
Machado, M.
Milanese, A.
Mandal, S.
Polini, A.
Gao, J.
Islam, R.
Zimmermann, F.
Chetvertkova, V.
Yamazaki, Y.
Rinolfi, L.
Blümlein, J.
Polifka, R.
Armesto, N.
Dupraz, K.
Sultansoy, S.
Cornell, A. S.
Wang, Z. S.
Boonekamp, M.
Kaya, U.
Moch, S.
Kilic, A.
Marzani, S.
Aksakal, H.
Schirm, K.
Mcintosh, P.
Perini, D.
D’Onofrio, M.
Rimmer, R.
Boroun, G. R.
Radescu, V.
Martin, R.
Guzey, V.
Thonet, P.
Navarra, F.
Stocchi, A.
Bracco, C.
Henry, J.
Schopper, H.
Bottura, L.
Ari, V.
Shen, X.
Levonian, S.
Sun, H.
Douglas, D.
Ten-Kate, A. T.
Tang, Y.
Zhu, G.
Zurita, J.
Cole, B.
Poulose, P.
Ferreiro, E. G.
Hu, N.
Forte, S.
Xu, T.
Klein, M.
Guo, Y. C.
Seryi, A.
Vallerand, C.
Bonvini, M.
Kluth, S.
Morgan, T.
Zhu, S.
Glazov, A.
Zenaiev, O.
Pupkov, Y. A.
Gwenlan, C.
Calaga, R.
Kuze, M.
Placakyte, R.
Pilicer, E.
Bailey, S.
Hammad, A.
Hautmann, F.
Arduini, G.
Liu, W.
Walker, D.
Jones, T.
Song, M.
Kuday, S.
Hobbs, T. J.
Rojo, J.
Curtin, D.
Antusch, S.
Mellado, B.
Yaguna, C. E.
Khanpour, H.
Schott, M.
Behera, S.
Vilella, E.
Iwamoto, S.
Jowett, J. M.
Opis:: The Large Hadron–Electron Collider (LHeC) is designed to move the field of deep inelastic scattering (DIS) to the energy and intensity frontier of particle physics. Exploiting energy-recovery technology, it collides a novel, intense electron beam with a proton or ion beam from the High-Luminosity Large Hadron Collider (HL-LHC). The accelerator and interaction region are designed for concurrent electron–proton and proton–proton operations. This report represents an update to the LHeC’s conceptual design report (CDR), published in 2012. It comprises new results on the parton structure of the proton and heavier nuclei, QCD dynamics, and electroweak and top-quark physics. It is shown how the LHeC will open a new chapter of nuclear particle physics by extending the accessible kinematic range of lepton–nucleus scattering by several orders of magnitude. Due to its enhanced luminosity and large energy and the cleanliness of the final hadronic states, the LHeC has a strong Higgs physics programme and its own discovery potential for new physics. Building on the 2012 CDR, this report contains a detailed updated design for the energy-recovery electron linac (ERL), including a new lattice, magnet and superconducting radio-frequency technology, and further components. Challenges of energy recovery are described, and the lower-energy, high-current, three-turn ERL facility, PERLE at Orsay, is presented, which uses the LHeC characteristics serving as a development facility for the design and operation of the LHeC. An updated detector design is presented corresponding to the acceptance, resolution, and calibration goals that arise from the Higgs and parton-density-function physics programmes. This paper also presents novel results for the Future Circular Collider in electron–hadron (FCC-eh) mode, which utilises the same ERL technology to further extend the reach of DIS to even higher centre-of-mass energies.
Dostawca treści:: Repozytorium Uniwersytetu Jagiellońskiego

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