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IRIS
Particle physics has arrived at an important moment of its history. The discovery of the Higgs boson, with a mass of 125 GeV, completes the matrix of particles and interactions that has constituted the “Standard Model” for several decades. This model is a consistent and predictive theory, which has so far proven successful at describing all phenomena accessible to collider experiments. On the other hand, several experimental facts do require the extension of the Standard Model and explanations are needed for observations such as the domination of matter over antimatter, the evidence for dark matter and the non-zero neutrino masses. Theoretical issues that need to be addressed include the hierarchy problem, the neutrality of the Universe, the stability of the Higgs boson mass upon quantum corrections and the strong CP problem. This report contains the description of a novel research infrastructure based on a highest-luminosity energy frontier electron-positron collider (FCC-ee) to address the open questions of modern physics. It will be a general precision instrument for the continued in-depth exploration of nature at the smallest scales, optimised to measure precisely the properties of the Higgs boson at the per-cent level, the Z and W bosons, the top quark and the Higgs coupling to the Z at the per-mil level. FCC-ee will provide unprecedented sensitivity to signs of new physics appearing either in the form of small deviations from the Standard Model or as rare decay processes. This collider will be implemented in stages, successively spanning the entire energy range from the Z pole over the WW threshold and H production peak to the t"t" ̅ threshold. Most of the infrastructure (e.g. underground structures, surface sites, electrical distribution, cooling & ventilation, RF systems) can be directly re-used for a subsequent highest-energy hadron collider (described in the FCC conceptual design report volume 3), serving the world-wide particle-physics community in a highly synergetic and cost-effective manner throughout the 21st century. The European Strategy for Particle Physics (ESPP) update 2013 stated “To stay at the forefront of particle physics, Europe needs to be in a position to propose an ambitious post-LHC accelerator project at CERN by the time of the next Strategy update”. The FCC study has implemented the ESPP recommendation by developing a long-term vision for an “accelerator project in a global context”. This document describes the detailed design and preparation of a construction project for a post-LHC circular lepton collider “in collaboration with national institutes, laboratories and universities worldwide”, and enhanced by a strong participation of industrial partners. Now, a coordinated preparation effort can be based on a core of an ever-growing consortium of already more than 135 institutes worldwide. The technology for constructing a high-energy, highest-luminosity circular lepton collider exists today. The FCC-ee concept comprises a power-saving twin-aperture magnet system, a continuous top-up injection scheme for stable operation and maximum integrated luminosity. Combined with an energy staging scheme, the FCC-ee represents the most efficient and most sustainable route for executing the research required to discover signs of new physics beyond the Standard Model. The step-wise energy increase of the FCC-ee does not require any additional civil engineering activities. Strategic R&D; for FCC-ee aims at minimising construction cost and energy consumption, while maximising the socio-economic impact. It will mitigate residual technology-related risks and ensure that industry can benefit from an acceptable economic utility. Concerning the implementation, a preparatory phase of about eight years is both necessary and adequate to establish the project governance and organisation structures, building the international machine and experiment consortia, developing a territorial implementation plan in agreement with the host-states’ requirements, optimising the disposal of land and underground volumes and preparing the civil engineering project. Such a large-scale, international fundamental research infrastructure, tightly involving industrial partners and providing training at all education levels, will be a strong motor of economic and societal development in all participating nations. The FCC study has implemented a set of actions towards a coherent vision for the world-wide high-energy and particle physics community, providing a collaborative framework for topically complementary and geographically well-balanced contributions. This conceptual design report lays the foundation for a subsequent infrastructure preparatory and technical design phase.
FCC-ee: The Lepton Collider
Abada, A.;Abbrescia, M.;AbdusSalam, S. S.;Abdyukhanov, I.;Abelleira Fernandez, J.;Abramov, A.;Aburaia, M.;Acar, A. O.;Adzic, P. R.;Agrawal, P.;Aguilar-Saavedra, J. A.;Aguilera-Verdugo, J. J.;Aiba, M.;Aichinger, I.;Aielli, G.;Akay, A.;Akhundov, A.;Aksakal, H.;Albacete, J. L.;Albergo, S.;Alekou, A.;Aleksa, M.;Aleksan, R.;Alemany Fernandez, R. M.;Alexahin, Y.;Alía, R. G.;Alioli, S.;Alipour Tehrani, N.;Allanach, B. C.;Allport, P. P.;Altınlı, M.;Altmannshofer, W.;Ambrosio, G.;Amorim, D.;Amstutz, O.;Anderlini, L.;Andreazza, A.;Andreini, M.;Andriatis, A.;Andris, C.;Andronic, A.;Angelucci, M.;Antinori, F.;Antipov, S. A.;Antonelli, M.;Antonello, M.;Antonioli, P.;Antusch, S.;Anulli, F.;Apolinário, L.;Apollinari, G.;Apollonio, A.;Appelö, D.;Appleby, R. B.;Apyan, A.;Apyan, A.;Arbey, A.;Arbuzov, A.;Arduini, G.;Arı, V.;Arias, S.;Armesto, N.;Arnaldi, R.;Arsenyev, S. A.;Arzeo, M.;Asai, S.;Aslanides, E.;Aßmann, R. 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S.;Etisken, O.;Etzion, E.;Fabbricatore, P.;Falkowski, A.;Falou, A.;Faltova, J.;Fan, J.;Fanò, L.;Farilla, A.;Farinelli, R.;Farinon, S.;Faroughy, D. A.;Fartoukh, S. D.;Faus-Golfe, A.;Fawcett, W. J.;Felici, G.;Felsberger, L.;Ferdeghini, C.;Fernandez Navarro, A. M.;Fernández-Téllez, A.;Ferradas Troitino, J.;Ferrara, G.;Ferrari, R.;Ferreira, L.;Ferreira da Silva, P.;Ferrera, G.;Ferro, F.;Fiascaris, M.;Fiorendi, S.;Fiorio, C.;Fischer, O.;Fischer, E.;Flieger, W.;Florio, M.;Fonnesu, D.;Fontanesi, E.;Foppiani, N.;Foraz, K.;Forkel-Wirth, D.;Forte, S.;Fouaidy, M.;Fournier, D.;Fowler, T.;Fox, J.;Francavilla, P.;Franceschini, R.;Franchino, S.;Franco, E.;Freitas, A.;Fuks, B.;Furukawa, K.;Furuseth, S. V.;Gabrielli, E.;Gaddi, A.;Galanti, M.;Gallo, E.;Ganjour, S.;Gao, J.;Gao, J.;Garcia Diaz, V.;García Pérez, M.;García Tabarés, L.;Garion, C.;Garzelli, M. V.;Garzia, I.;Gascon-Shotkin, S. M.;Gaudio, G.;Gay, P.;Ge, S. -F.;Gehrmann, T.;Genest, M. H.;Gerard, R.;Gerigk, F.;Gerwig, H.;Giacomelli, P.;Giagu, S.;Gianfelice-Wendt, E.;Gianotti, F.;Giffoni, F.;Gilardoni, S. S.;Gil Costa, M.;Giovannetti, M.;Giovannozzi, M.;Giubellino, P.;Giudice, G. F.;Giunta, A.;Gladilin, L. K.;Glukhov, S.;Gluza, J.;Gobbi, G.;Goddard, B.;Goertz, F.;Golling, T.;Goncalves, V. P.;Goncalves Netto, D.;Gonçalo, R.;Gonzalez Gomez, L. A.;Gorgi Zadeh, S.;Gorine, G.;Gorini, E.;Gourlay, S. A.;Gouskos, L.;Grancagnolo, F.;Grassellino, A.;Grau, A.;Graverini, E.;Gray, H. M.;Greco, M.;Greco, M.;Grenard, J. -L.;Grimm, O.;Grojean, C.;Gromov, V. A.;Grosse-Oetringhaus, J. F;Grudiev, A.;Grzanka, K.;Gu, J.;Guadagnoli, D.;Guidi, V.;Guiducci, S.;Guillermo Canton, G.;Günaydin, Y. O.;Gupta, R.;Gupta, R. S.;Gutierrez, J.;Gutleber, J.;Guyot, C.;Guzey, V.;Gwenlan, C.;Haberstroh, C.;Hacışahinoğlu, B.;Haerer, B.;Hahn, K.;Hahn, T.;Hammad, A.;Han, C.;Hance, M.;Hannah, A.;Harris, P. C.;Hati, C.;Haug, S.;Hauptman, J.;Haurylavets, V.;He, H. -J.;Hegglin, A.;Hegner, B.;Heinemann, K.;Heinemeyer, S.;Helsens, C.;Henriques, A.;Henriques, A.;Hernandez, P.;Hernández-Pinto, R. J.;Hernandez-Sanchez, J.;Herzig, T.;Hiekkanen, I.;Hillert, W.;Hoehn, T.;Hofer, M.;Höfle, W.;Holdener, F.;Holleis, S.;Holzer, B.;Hong, D. K.;Honorato, C. G.;Hopkins, S. C.;Hrdinka, J.;Hug, F.;Humann, B.;Humer, H.;Hurth, T.;Hutton, A.;Iacobucci, G.;Ibarrola, N.;Iconomidou-Fayard, L.;Ilyina-Brunner, K.;Incandela, J.;Infantino, A.;Ippolito, V.;Ishino, M.;Islam, R.;Ita, H.;Ivanovs, A.;Iwamoto, S.;Iyer, A.;Izquierdo Bermudez, S.;Jadach, S.;Jamin, D. O.;Janot, P.;Jarry, P.;Jeff, A.;Jenny, P.;Jensen, E.;Jensen, M.;Jiang, X.;Jiménez, J. M.;Jones, M. A.;Jones, O. R.;Jowett, J. M.;Jung, S.;Kaabi, W.;Kado, M.;Kahle, K.;Kalinovskaya, L.;Kalinowski, J.;Kamenik, J. F.;Kannike, K.;Kara, S. O.;Karadeniz, H.;Karaventzas, V.;Karpov, I.;Kartal, S.;Karyukhin, A.;Kashikhin, V.;Katharina Behr, J.;Kaya, U.;Keintzel, J.;Keinz, P. A.;Keppel, K.;Kersevan, R.;Kershaw, K.;Khanpour, H.;Khatibi, S.;Khatiri Yanehsari, M.;Khoze, V. V.;Kieseler, J.;Kilic, A.;Kilpinen, A.;Kim, Y. -K.;Kim, D. W.;Klein, U.;Klein, M.;Kling, F.;Klinkenberg, N.;Klöppel, S.;Klute, M.;Klyukhin, V. I.;Knecht, M.;Kniehl, B.;Kocak, F.;Koeberl, C.;Kolano, A. M.;Kollegger, A.;Kołodziej, K.;Kolomiets, A. A.;Komppula, J.;Koop, I.;Koppenburg, P.;Koratzinos, M.;Kordiaczyńska, M.;Korjik, M.;Kortner, O.;Kostka, P.;Kotlarski, W.;Kotnig, C.;Köttig, T.;Kotwal, A. V.;Kovalenko, A. D.;Kowalski, S.;Kozaczuk, J.;Kozlov, G. A.;Kozub, S. S.;Krainer, A. M.;Kramer, T.;Krämer, M.;Krammer, M.;Krasnov, A. A.;Krauss, F.;Kravalis, K.;Kretzschmar, L.;Kriske, R. M.;Kritscher, H.;Krkotic, P.;Kroha, H.;Kucharczyk, M.;Kuday, S.;Kuendig, A.;Kuhlmann, G.;Kulesza, A.;Kumar, M.;Kumar, M.;Kusina, A.;Kuttimalai, S.;Kuze, M.;Kwon, T.;Lackner, F.;Lackner, M.;La Francesca, E.;Laine, M.;Lamanna, G.;La Mendola, S.;Lançon, E.;Landsberg, G.;Langacker, P.;Lange, C.;Langner, A.;Lankford, A. J.;Lansberg, J. P.;Lari, T.;Laycock, P. J.;Lebrun, P.;Lechner, A.;Lee, K.;Lee, S.;Lee, R.;Lefevre, T.;Le Guen, P.;Lehtinen, T.;Leith, S. B.;Lenzi, P.;Leogrande, E.;Leonidopoulos, C.;Leon-Monzon, I.;Lerner, G.;Leroy, O.;Lesiak, T.;Lévai, P.;Leveratto, A.;Levichev, E.;Li, G.;Li, S.;Li, R.;Liberati, D.;Liepe, M.;Lissauer, D. A.;Liu, Z.;Lobko, A.;Locci, E.;Logothetis Agaliotis, E.;Lombardo, M. P.;Long, A. J.;Lorin, C.;Losito, R.;Louzguiti, A.;Low, I.;Lucchesi, D.;Lucchini, M. T.;Luciani, A.;Lueckhof, M.;Lunt, A. J. G.;Luzum, M.;Lyubimtsev, D. A.;Maggiora, M.;Magnin, N.;Mahmoud, M. A.;Mahmoudi, F.;Maitre, J.;Makarenko, V.;Malagoli, A.;Malclés, J.;Malgeri, L.;Mallon, P. J.;Maltoni, F.;Malvezzi, S.;Malyshev, O. B.;Mancinelli, G.;Mandrik, P.;Manfrinetti, P.;Mangano, M.;Manil, P.;Mannelli, M.;Marchiori, G.;Marhauser, F.;Mariani, V.;Marinozzi, V.;Mariotto, S.;Marquard, P.;Marquet, C.;Marriott-Dodington, T.;Martin, R.;Martin, O.;Martin Camalich, J.;Martinez, T.;Martinez Bruzual, H.;Martínez-Hernández, M. I.;Martins, D. E.;Marzani, S.;Marzocca, D.;Marzola, L.;Masciocchi, S.;Masina, I.;Massimiliano, A.;Massironi, A.;Masubuchi, T.;Matveev, V. A.;Mazzoni, M. A.;McCullough, M.;McIntosh, P. A.;Meade, P.;Medina, L.;Meier, A.;Meignan, J.;Mele, B.;Mendes Saraiva, J. G.;Menez, F.;Mentink, M.;Meoni, E.;Meridiani, P.;Merk, M.;Mermod, P.;Mertens, V.;Mether, L.;Métral, E.;Migliorati, M.;Milanese, A.;Milardi, C.;Milhano, G.;Militsyn, B. L.;Millet, F.;Minashvili, I.;Minervini, J. V.;Miralles, L. S.;Mirarchi, D.;Mishima, S.;Missiaen, D. P.;Mitselmakher, G.;Mitsuhashi, T.;Mnich, J.;Mohammadi Najafabadi, M.;Mohapatra, R. N.;Mokhov, N.;Molson, J. 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F.;Palmieri, E.;Palumbo, L.;Pampaloni, A.;Pan, R. -Q.;Panareo, M.;Panella, O.;Panico, G.;Panizzo, G.;Pankov, A. A.;Pantsyrny, V.;Papadopoulos, C. G.;Papaefstathiou, A.;Papaphilippou, Y.;Parker, M. A.;Parma, V.;Pasquali, M.;Patra, S. K.;Patterson, R.;Paukkunen, H.;Pauss, F.;Peggs, S.;Penttinen, J. -P.;Peón, G.;Perepelkin, E. E.;Perez, E.;Perez, J. C.;Perez, G.;Pérez, F.;Perez Codina, E.;Perez Morales, J.;Perfilov, M.;Pernegger, H.;Peruzzi, M.;Pes, C.;Peters, K.;Petracca, S.;Petriello, F.;Pezzotti, L.;Pfeiffer, S.;Piccinini, F.;Pieloni, T.;Pierini, M.;Pikhartova, H.;Pikurs, G.;Pilicer, E.;Piminov, P.;Pira, C.;Pittau, R.;Płaczek, W.;Plagge, M.;Plehn, T.;Pleier, M. -A.;Płoskoń, M.;Podeur, M.;Podlech, H.;Podzorny, T.;Poggioli, L.;Poiron, A.;Polesello, G.;Poli Lener, M.;Polini, A.;Polinski, J.;Polozov, S. M.;Ponce, L.;Pont, M.;Pontecorvo, L.;Portaluri, T.;Potamianos, K.;Prasse, C.;Prausa, M.;Preinerstorfer, A.;Premat, E.;Price, T.;Primavera, M.;Prino, F.;Prioli, M.;Proudfoot, J.;Provino, A.;Pugnat, T.;Pukhaeva, N.;Puławski, S.;Pulikowski, D.;Punzi, G.;Putti, M.;Pyarelal, A.;Quack, H.;Quispe, M.;Racioppi, A.;Rafique, H.;Raginel, V.;Raidal, M.;Ramírez-Uribe, N. S.;Ramsey-Musolf, M. J;Rata, R.;Ratoff, P.;Ravotti, F.;Rebello Teles, P.;Reboud, M.;Redaelli, S.;Renner, E.;Rentería-Olivo, A. E.;Rescigno, M.;Reuter, J.;Ribon, A.;Ricci, A. M.;Riegler, W.;Riemann, S.;Riemann, B.;Riemann, T.;Rifflet, J. M.;Rimmer, R. A.;Rinaldesi, R.;Rinolfi, L.;Rios Rubiras, O.;Risselada, T.;Rivetti, A.;Rivkin, L.;Rizzo, T.;Robens, T.;Robert, F.;Robson, A. 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2019-01-01
Abstract
Particle physics has arrived at an important moment of its history. The discovery of the Higgs boson, with a mass of 125 GeV, completes the matrix of particles and interactions that has constituted the “Standard Model” for several decades. This model is a consistent and predictive theory, which has so far proven successful at describing all phenomena accessible to collider experiments. On the other hand, several experimental facts do require the extension of the Standard Model and explanations are needed for observations such as the domination of matter over antimatter, the evidence for dark matter and the non-zero neutrino masses. Theoretical issues that need to be addressed include the hierarchy problem, the neutrality of the Universe, the stability of the Higgs boson mass upon quantum corrections and the strong CP problem. This report contains the description of a novel research infrastructure based on a highest-luminosity energy frontier electron-positron collider (FCC-ee) to address the open questions of modern physics. It will be a general precision instrument for the continued in-depth exploration of nature at the smallest scales, optimised to measure precisely the properties of the Higgs boson at the per-cent level, the Z and W bosons, the top quark and the Higgs coupling to the Z at the per-mil level. FCC-ee will provide unprecedented sensitivity to signs of new physics appearing either in the form of small deviations from the Standard Model or as rare decay processes. This collider will be implemented in stages, successively spanning the entire energy range from the Z pole over the WW threshold and H production peak to the t"t" ̅ threshold. Most of the infrastructure (e.g. underground structures, surface sites, electrical distribution, cooling & ventilation, RF systems) can be directly re-used for a subsequent highest-energy hadron collider (described in the FCC conceptual design report volume 3), serving the world-wide particle-physics community in a highly synergetic and cost-effective manner throughout the 21st century. The European Strategy for Particle Physics (ESPP) update 2013 stated “To stay at the forefront of particle physics, Europe needs to be in a position to propose an ambitious post-LHC accelerator project at CERN by the time of the next Strategy update”. The FCC study has implemented the ESPP recommendation by developing a long-term vision for an “accelerator project in a global context”. This document describes the detailed design and preparation of a construction project for a post-LHC circular lepton collider “in collaboration with national institutes, laboratories and universities worldwide”, and enhanced by a strong participation of industrial partners. Now, a coordinated preparation effort can be based on a core of an ever-growing consortium of already more than 135 institutes worldwide. The technology for constructing a high-energy, highest-luminosity circular lepton collider exists today. The FCC-ee concept comprises a power-saving twin-aperture magnet system, a continuous top-up injection scheme for stable operation and maximum integrated luminosity. Combined with an energy staging scheme, the FCC-ee represents the most efficient and most sustainable route for executing the research required to discover signs of new physics beyond the Standard Model. The step-wise energy increase of the FCC-ee does not require any additional civil engineering activities. Strategic R&D; for FCC-ee aims at minimising construction cost and energy consumption, while maximising the socio-economic impact. It will mitigate residual technology-related risks and ensure that industry can benefit from an acceptable economic utility. Concerning the implementation, a preparatory phase of about eight years is both necessary and adequate to establish the project governance and organisation structures, building the international machine and experiment consortia, developing a territorial implementation plan in agreement with the host-states’ requirements, optimising the disposal of land and underground volumes and preparing the civil engineering project. Such a large-scale, international fundamental research infrastructure, tightly involving industrial partners and providing training at all education levels, will be a strong motor of economic and societal development in all participating nations. The FCC study has implemented a set of actions towards a coherent vision for the world-wide high-energy and particle physics community, providing a collaborative framework for topically complementary and geographically well-balanced contributions. This conceptual design report lays the foundation for a subsequent infrastructure preparatory and technical design phase.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11587/431480
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