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    Wyświetlanie 1-7 z 7
    Tytuł:
    The CERN gamma factory initiative : an ultra-high intensity gamma source
    Autorzy:
    Stoehlker, T.
    Alikhanyan, A. I.
    Wu, Y. K.
    Goddard, B.
    Jowett, J. M.
    Lebedev, P. N.
    Budker, D.
    Castelli, F.
    Weber, G.
    Petrillo, V.
    Alemany Fernandez, R.
    Petrenko, A.
    Schaumann, M.
    Zomer, F.
    Chaikovska, I.
    Kroeger, F.
    Dzierżęga, Krzysztof
    Czodrowski, P.
    Bieroń, Jacek
    Antsiferov, P. S.
    Yin-Vallgren, C.
    Chehab, R.
    Cassou, K.
    Apyan, A.
    Bartosik, H.
    Hirlander, S.
    Pustelny, Szymon
    Kersevan, R.
    Shevelko, V. P.
    Dupraz, K.
    Curatolo, C.
    Krasny, M. W.
    Biancacci, N.
    Manglunki, D.
    Zolotorev, M. S.
    Bessonov, E. G.
    Lamont, M.
    Kowalska, M.
    Zimmermann, F.
    Płaczek, Wiesław
    Martens, A.
    Serafini, L.
    Wydawca:
    Joint Accelerator Conferences Website
    Opis:
    This contribution discusses the possibility of broadening the present CERN research programme making use of a novel concept of light source. The proposed, Partially Stripped Ion beam driven, light source is the backbone of the Gamma Factory (GF) initiative. It could be realized at CERN by using the infrastructure of the already existing accelerators. It could push the intensity limits of the presently operating light-sources by up to 7 orders of magnitude, reaching fluxes of 10¹⁷ photons/s in the interesting gamma-ray energy domain between 1 MeV and 400 MeV. The GF light-source cannot be replaced, in this energy domain, by a FEL source as long as the multi TeV electron beams are not available. Its intensity is beyond the reach of the Inverse Compton Scattering sources. The unprecedented-intensity, energy-tuned gamma beams, together with the gamma-beams-driven secondary beams of polarized leptons, neutrinos, neutrons and radioactive ions are the basic research tools of the proposed Gamma Factory. A broad spectrum of new opportunities, in a vast domain of uncharted fundamental and applied physics territories, could be opened by the Gamma Factory research programme.
    Dostawca treści:
    Repozytorium Uniwersytetu Jagiellońskiego
    Inne
    Tytuł:
    The Gamma Factory Project at CERN : a new generation of research tools made of light
    Autorzy:
    Derevianko, A.
    Nutarelli, D.
    Antsiferov, P. S.
    Goddard, B.
    Lefevre, T.
    Tolstikhina, I.
    Bruce, R.
    Gorzawski, A.
    Zolotorev, M. S.
    Bogacz, A.
    Peinaud, Y.
    Martens, A.
    Schaumann, M.
    Apyan, A.
    Redaelli, S.
    Pustelny, Szymon
    Manglunki, D.
    Stoehlker, T.
    Krasny, M. W.
    Alden, S. E.
    Bessonov, E. G.
    Zomer, F.
    Biancacci, N.
    Cassou, K.
    Dupraz, K.
    Kowalska, M.
    Bieroń, Jacek
    Bosco, A.
    Dutheil, Y.
    Yin-Vallgren, C.
    Molson, J.
    Surzhykov, A.
    Chaikovska, I.
    Velotti, F.
    Zanetti, M.
    Budker, D.
    Curatolo, C.
    Fedosseev, V.
    Jowett, J. M.
    Nevay, L. J.
    Wu, Y. K.
    Marsh, B.
    Abramov, A.
    Serafini, L.
    Shevelko, V. P.
    Petrenko, A.
    Kuchler, D.
    Scrivens, R.
    Kersevan, R.
    Dzierżęga, Krzysztof
    Hirlander, S.
    Fuster Martinez, N.
    Bartosik, H.
    Płaczek, Wiesław
    Petrillo, V.
    Czodrowski, P.
    Zimmermann, F.
    Weber, G.
    Kroeger, F.
    Sapinski, M.
    Castelli, F.
    Gibson, S. M.
    Rochester, S.
    Lamont, M.
    Alemany Fernandez, R.
    Opis:
    The Gamma Factory project offers the possibility of creating novel research tools by producing relativistic beams of highly ionised atoms in CERN’s accelerator complex and exciting their atomic degrees of freedom by lasers to produce strongly collimated high-energy photon beams. Intensity of such beams would exceed by several orders of magnitude the ones offered by the presently operating light sources, in the particularly interesting energy domain from about 100 keV to above 400 MeV. In this energy regime, the high-intensity photon beams can be used to produce secondary beams of polarised electrons, polarised positrons, polarised muons, neutrinos, neutrons and radioactive ions. New research opportunities in many domains of physics, from particle physics through nuclear physics to atomic physics, can be opened by the Gamma Factory scientific programme based on the above primary and secondary beams. Except for basic research, it offers also a possibility for various application studies, e.g. in medical physics and nuclear power.
    Dostawca treści:
    Repozytorium Uniwersytetu Jagiellońskiego
    Inne
    Tytuł:
    Gamma Factory for CERN initiative : progress report
    Autorzy:
    Stoehlker, T.
    Velotti, F. M.
    Lefevre, T.
    Sapinski, M.
    Surzhykov, A.
    Dutheil, Y.
    Wu, Y. K.
    Goddard, B.
    Molson, J.
    Tolstikhina, I.
    Budker, D.
    Castelli, F.
    Weber, G.
    Nevay, L. J.
    Derevianko, A.
    Kuchler, D.
    Petrillo, V.
    Alemany Fernandez, R.
    Petrenko, A.
    Schaumann, M.
    Zomer, F.
    Chaikovska, I.
    Krasny, M.
    Abramov, A.
    Bogacz, A.
    Kroeger, F.
    Dzierżęga, Krzysztof
    Czodrowski, P.
    Naturelli, D.
    Bessonov, E.
    Bieroń, Jacek
    Gorzawski, A.
    Redaelli, S.
    Alden, S.
    Scrivens, R.
    Rochester, S.
    Bosco, A.
    Cassou, K.
    Gibson, S.
    Marsh, B.
    Peinaud, Y.
    Apyan, A.
    Antsiferov, P.
    Jowett, J.
    Bartosik, H.
    Hirlander, S.
    Pustelny, Szymon
    Yin Vallgren, C.
    Kersevan, R.
    Zanetti, M.
    Bruce, R.
    Zolotorev, M.
    Dupraz, K.
    Curatolo, C.
    Shevelko, V.
    Biancacci, N.
    Manglunki, D.
    Fedosseev, V.
    Lamont, M.
    Kowalska, M.
    Płaczek, Wiesław
    Zimmermann, F.
    Martens, A.
    Fuster Martinez, N.
    Serafini, L.
    Opis:
    The Gamma Factory (GF) initiative proposes to use partially stripped ion (PSI) beams as drivers of a new type of high-intensity and high-energy (0.1–400 MeV) photon source. As part of the ongoing Physics Beyond Collider studies, initial beam tests were carried out in 2017 and 2018 at the SPS and LHC with partially stripped xenon and lead beams. This contribution discusses the results of these tests and the preparations for the next GF R&D step: the proof-of-principle experiment at the SPS to study interaction of PSI beams with the laser light.
    Dostawca treści:
    Repozytorium Uniwersytetu Jagiellońskiego
    Inne
    Tytuł:
    Gamma factory at CERN : design of a proof-of-principle experiment
    Autorzy:
    Derevianko, A.
    Goddard, B.
    Bruce, R.
    Bogacz, A.
    Fedosseev, V. N.
    Schaumann, M.
    Apyan, A.
    Stoehlker, T.
    Martens, A.
    Manglunki, D.
    Pustelny, Szymon
    Krasny, M. W.
    Alden, S. E.
    Bessonov, E. G.
    Zomer, F.
    Biancacci, N.
    Cassou, K.
    Dupraz, K.
    Kowalska, M.
    Bieroń, Jacek
    Dutheil, Y.
    Bosco, A.
    Molson, J.
    Hirlaender, S.
    Chaikovska, I.
    Budker, D.
    Curatolo, C.
    Jowett, J. M.
    Nevay, L. J.
    Wu, Y. K.
    Serafini, L.
    Petrenko, A.
    Kersevan, R.
    Dzierżęga, Krzysztof
    Bartosik, H.
    Petrillo, V.
    Alemany-Fernandez, R.
    Płaczek, Wiesław
    Czodrowski, P.
    Zimmermann, F.
    Weber, G.
    Kroeger, F.
    Shevelko, V.
    Sapinski, M.
    Castelli, F.
    Gibson, S. M.
    Zolotorev, M.
    Lamont, M.
    Wydawca:
    JACoW Publishing
    Opis:
    The Gamma Factory (GF) initiative proposes to create novel research tools at CERN by producing, accelerating and storing highly relativistic partially stripped ion beams in the LHC rings and by exciting their atomic degrees of freedom by lasers, to produce high-energy photon beams. Their intensity would be several orders of magnitude higher than those of the presently operating light sources in the particularly interesting gamma-ray energy domain reaching up to 400 MeV. In this energy domain, the high-intensity photon beams can be used to produce secondary beams of polarized electrons, polarized positrons, polarized muons, neutrinos, neutrons and radioactive ions. Over the years 2017-2018 we have demonstrated that these partially stripped ion beams can be successfully produced, accelerated and stored in the CERN accelerator complex, including the LHC. The next step of the project is to build a proof of principle experiment in the SPS to validate the principal GF concepts. This contribution will present the initial conceptual design of this experiment along with its main challenge - the demonstration of the fast cooling method of partially stripped ion beams.
    Dostawca treści:
    Repozytorium Uniwersytetu Jagiellońskiego
    Inne
    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
    Artykuł
      Wyświetlanie 1-7 z 7

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