C. Grefe - The CALICE Collaboration

C. Grefe
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C. Grefe
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The CALICE Collaboration
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High Energy Physics - Experiment (13)
 
Physics - Instrumentation and Detectors (8)
 
High Energy Physics - Phenomenology (2)
 
Physics - Accelerator Physics (2)

Publications Authored By C. Grefe

2016Aug
Authors: H. Abramowicz, A. Abusleme, K. Afanaciev, N. Alipour Tehrani, C. Balázs, Y. Benhammou, M. Benoit, B. Bilki, J. -J. Blaising, M. J. Boland, M. Boronat, O. Borysov, I. Božović-Jelisavčić, M. Buckland, S. Bugiel, P. N. Burrows, T. K. Charles, W. Daniluk, D. Dannheim, R. Dasgupta, M. Demarteau, M. A. Díaz Gutierrez, G. Eigen, K. Elsener, U. Felzmann, M. Firlej, E. Firu, T. Fiutowski, J. Fuster, M. Gabriel, F. Gaede, I. García, V. Ghenescu, J. Goldstein, S. Green, C. Grefe, M. Hauschild, C. Hawkes, D. Hynds, M. Idzik, G. Kačarević, J. Kalinowski, S. Kananov, W. Klempt, M. Kopec, M. Krawczyk, B. Krupa, M. Kucharczyk, S. Kulis, T. Laštovička, T. Lesiak, A. Levy, I. Levy, L. Linssen, S. Lukić, A. A. Maier, V. Makarenko, J. S. Marshall, K. Mei, G. Milutinović-Dumbelović, J. Moroń, A. Moszczyński, D. Moya, R. M. Münker, A. Münnich, A. T. Neagu, N. Nikiforou, K. Nikolopoulos, A. Nürnberg, M. Pandurović, B. Pawlik, E. Perez Codina, I. Peric, M. Petric, F. Pitters, S. G. Poss, T. Preda, D. Protopopescu, R. Rassool, S. Redford, J. Repond, A. Robson, P. Roloff, E. Ros, O. Rosenblat, A. Ruiz-Jimeno, A. Sailer, D. Schlatter, D. Schulte, N. Shumeiko, E. Sicking, F. Simon, R. Simoniello, P. Sopicki, S. Stapnes, R. Ström, J. Strube, K. P. Świentek, M. Szalay, M. Tesař, M. A. Thomson, J. Trenado, U. I. Uggerhøj, N. van der Kolk, E. van der Kraaij, M. Vicente Barreto Pinto, I. Vila, M. Vogel Gonzalez, M. Vos, J. Vossebeld, M. Watson, N. Watson, M. A. Weber, H. Weerts, J. D. Wells, L. Weuste, A. Winter, T. Wojtoń, L. Xia, B. Xu, A. F. Żarnecki, L. Zawiejski, I. -S. Zgura

The Compact Linear Collider (CLIC) is an option for a future e+e- collider operating at centre-of-mass energies up to 3 TeV, providing sensitivity to a wide range of new physics phenomena and precision physics measurements at the energy frontier. This paper presents the Higgs physics reach of CLIC operating in three energy stages, sqrt(s) = 350 GeV, 1.4 TeV and 3 TeV. Read More

2016Aug
Authors: The CLIC, CLICdp collaborations, :, M. J. Boland, U. Felzmann, P. J. Giansiracusa, T. G. Lucas, R. P. Rassool, C. Balazs, T. K. Charles, K. Afanaciev, I. Emeliantchik, A. Ignatenko, V. Makarenko, N. Shumeiko, A. Patapenka, I. Zhuk, A. C. Abusleme Hoffman, M. A. Diaz Gutierrez, M. Vogel Gonzalez, Y. Chi, X. He, G. Pei, S. Pei, G. Shu, X. Wang, J. Zhang, F. Zhao, Z. Zhou, H. Chen, Y. Gao, W. Huang, Y. P. Kuang, B. Li, Y. Li, J. Shao, J. Shi, C. Tang, X. Wu, L. Ma, Y. Han, W. Fang, Q. Gu, D. Huang, X. Huang, J. Tan, Z. Wang, Z. Zhao, T. Laštovička, U. Uggerhoj, T. N. Wistisen, A. Aabloo, K. Eimre, K. Kuppart, S. Vigonski, V. Zadin, M. Aicheler, E. Baibuz, E. Brücken, F. Djurabekova, P. Eerola, F. Garcia, E. Haeggström, K. Huitu, V. Jansson, V. Karimaki, I. Kassamakov, A. Kyritsakis, S. Lehti, A. Meriläinen, R. Montonen, T. Niinikoski, K. Nordlund, K. Österberg, M. Parekh, N. A. Törnqvist, J. Väinölä, M. Veske, W. Farabolini, A. Mollard, O. Napoly, F. Peauger, J. Plouin, P. Bambade, I. Chaikovska, R. Chehab, M. Davier, W. Kaabi, E. Kou, F. LeDiberder, R. Pöschl, D. Zerwas, B. Aimard, G. Balik, J. -P. Baud, J. -J. Blaising, L. Brunetti, M. Chefdeville, C. Drancourt, N. Geoffroy, J. Jacquemier, A. Jeremie, Y. Karyotakis, J. M. Nappa, S. Vilalte, G. Vouters, A. Bernard, I. Peric, M. Gabriel, F. Simon, M. Szalay, N. van der Kolk, T. Alexopoulos, E. N. Gazis, N. Gazis, E. Ikarios, V. Kostopoulos, S. Kourkoulis, P. D. Gupta, P. Shrivastava, H. Arfaei, M. K. Dayyani, H. Ghasem, S. S. Hajari, H. Shaker, Y. Ashkenazy, H. Abramowicz, Y. Benhammou, O. Borysov, S. Kananov, A. Levy, I. Levy, O. Rosenblat, G. D'Auria, S. Di Mitri, T. Abe, A. Aryshev, T. Higo, Y. Makida, S. Matsumoto, T. Shidara, T. Takatomi, Y. Takubo, T. Tauchi, N. Toge, K. Ueno, J. Urakawa, A. Yamamoto, M. Yamanaka, R. Raboanary, R. Hart, H. van der Graaf, G. Eigen, J. Zalieckas, E. Adli, R. Lillestøl, L. Malina, J. Pfingstner, K. N. Sjobak, W. Ahmed, M. I. Asghar, H. Hoorani, S. Bugiel, R. Dasgupta, M. Firlej, T. A. Fiutowski, M. Idzik, M. Kopec, M. Kuczynska, J. Moron, K. P. Swientek, W. Daniluk, B. Krupa, M. Kucharczyk, T. Lesiak, A. Moszczynski, B. Pawlik, P. Sopicki, T. Wojtoń, L. Zawiejski, J. Kalinowski, M. Krawczyk, A. F. Żarnecki, E. Firu, V. Ghenescu, A. T. Neagu, T. Preda, I-S. Zgura, A. Aloev, N. Azaryan, J. Budagov, M. Chizhov, M. Filippova, V. Glagolev, A. Gongadze, S. Grigoryan, D. Gudkov, V. Karjavine, M. Lyablin, A. Olyunin, A. Samochkine, A. Sapronov, G. Shirkov, V. Soldatov, A. Solodko, E. Solodko, G. Trubnikov, I. Tyapkin, V. Uzhinsky, A. Vorozhtov, E. Levichev, N. Mezentsev, P. Piminov, D. Shatilov, P. Vobly, K. Zolotarev, I. Bozovic Jelisavcic, G. Kacarevic, S. Lukic, G. Milutinovic-Dumbelovic, M. Pandurovic, U. Iriso, F. Perez, M. Pont, J. Trenado, M. Aguilar-Benitez, J. Calero, L. Garcia-Tabares, D. Gavela, J. L. Gutierrez, D. Lopez, F. Toral, D. Moya, A. Ruiz Jimeno, I. Vila, T. Argyropoulos, C. Blanch Gutierrez, M. Boronat, D. Esperante, A. Faus-Golfe, J. Fuster, N. Fuster Martinez, N. Galindo Muñoz, I. García, J. Giner Navarro, E. Ros, M. Vos, R. Brenner, T. Ekelöf, M. Jacewicz, J. Ögren, M. Olvegård, R. Ruber, V. Ziemann, D. Aguglia, N. Alipour Tehrani, A. Andersson, F. Andrianala, F. Antoniou, K. Artoos, S. Atieh, R. Ballabriga Sune, M. J. Barnes, J. Barranco Garcia, H. Bartosik, C. Belver-Aguilar, A. Benot Morell, D. R. Bett, S. Bettoni, G. Blanchot, O. Blanco Garcia, X. A. Bonnin, O. Brunner, H. Burkhardt, S. Calatroni, M. Campbell, N. Catalan Lasheras, M. Cerqueira Bastos, A. Cherif, E. Chevallay, B. Constance, R. Corsini, B. Cure, S. Curt, B. Dalena, D. Dannheim, G. De Michele, L. De Oliveira, N. Deelen, J. P. Delahaye, T. Dobers, S. Doebert, M. Draper, F. Duarte Ramos, A. Dubrovskiy, K. Elsener, J. Esberg, M. Esposito, V. Fedosseev, P. Ferracin, A. Fiergolski, K. Foraz, A. Fowler, F. Friebel, J-F. Fuchs, C. A. Fuentes Rojas, A. Gaddi, L. Garcia Fajardo, H. Garcia Morales, C. Garion, L. Gatignon, J-C. Gayde, H. Gerwig, A. N. Goldblatt, C. Grefe, A. Grudiev, F. G. Guillot-Vignot, M. L. Gutt-Mostowy, M. Hauschild, C. Hessler, J. K. Holma, E. Holzer, M. Hourican, D. Hynds, Y. Inntjore Levinsen, B. Jeanneret, E. Jensen, M. Jonker, M. Kastriotou, J. M. K. Kemppinen, R. B. Kieffer, W. Klempt, O. Kononenko, A. Korsback, E. Koukovini Platia, J. W. Kovermann, C-I. Kozsar, I. Kremastiotis, S. Kulis, A. Latina, F. Leaux, P. Lebrun, T. Lefevre, L. Linssen, X. Llopart Cudie, A. A. Maier, H. Mainaud Durand, E. Manosperti, C. Marelli, E. Marin Lacoma, R. Martin, S. Mazzoni, G. Mcmonagle, O. Mete, L. M. Mether, M. Modena, R. M. Münker, T. Muranaka, E. Nebot Del Busto, N. Nikiforou, D. Nisbet, J-M. Nonglaton, F. X. Nuiry, A. Nürnberg, M. Olvegard, J. Osborne, S. Papadopoulou, Y. Papaphilippou, A. Passarelli, M. Patecki, L. Pazdera, D. Pellegrini, K. Pepitone, E. Perez Codina, A. Perez Fontenla, T. H. B. Persson, M. Petrič, F. Pitters, S. Pittet, F. Plassard, R. Rajamak, S. Redford, Y. Renier, S. F. Rey, G. Riddone, L. Rinolfi, E. Rodriguez Castro, P. Roloff, C. Rossi, V. Rude, G. Rumolo, A. Sailer, E. Santin, D. Schlatter, H. Schmickler, D. Schulte, N. Shipman, E. Sicking, R. Simoniello, P. K. Skowronski, P. Sobrino Mompean, L. Soby, M. P. Sosin, S. Sroka, S. Stapnes, G. Sterbini, R. Ström, I. Syratchev, F. Tecker, P. A. Thonet, L. Timeo, H. Timko, R. Tomas Garcia, P. Valerio, A. L. Vamvakas, A. Vivoli, M. A. Weber, R. Wegner, M. Wendt, B. Woolley, W. Wuensch, J. Uythoven, H. Zha, P. Zisopoulos, M. Benoit, M. Vicente Barreto Pinto, M. Bopp, H. H. Braun, M. Csatari Divall, M. Dehler, T. Garvey, J. Y. Raguin, L. Rivkin, R. Zennaro, A. Aksoy, Z. Nergiz, E. Pilicer, I. Tapan, O. Yavas, V. Baturin, R. Kholodov, S. Lebedynskyi, V. Miroshnichenko, S. Mordyk, I. Profatilova, V. Storizhko, N. Watson, A. Winter, J. Goldstein, S. Green, J. S. Marshall, M. A. Thomson, B. Xu, W. A. Gillespie, R. Pan, M. A Tyrk, D. Protopopescu, A. Robson, R. Apsimon, I. Bailey, G. Burt, D. Constable, A. Dexter, S. Karimian, C. Lingwood, M. D. Buckland, G. Casse, J. Vossebeld, A. Bosco, P. Karataev, K. Kruchinin, K. Lekomtsev, L. Nevay, J. Snuverink, E. Yamakawa, V. Boisvert, S. Boogert, G. Boorman, S. Gibson, A. Lyapin, W. Shields, P. Teixeira-Dias, S. West, R. Jones, N. Joshi, R. Bodenstein, P. N. Burrows, G. B. Christian, D. Gamba, C. Perry, J. Roberts, J. A. Clarke, N. A. Collomb, S. P. Jamison, B. J. A. Shepherd, D. Walsh, M. Demarteau, J. Repond, H. Weerts, L. Xia, J. D. Wells, C. Adolphsen, T. Barklow, M. Breidenbach, N. Graf, J. Hewett, T. Markiewicz, D. McCormick, K. Moffeit, Y. Nosochkov, M. Oriunno, N. Phinney, T. Rizzo, S. Tantawi, F. Wang, J. Wang, G. White, M. Woodley

The Compact Linear Collider (CLIC) is a multi-TeV high-luminosity linear e+e- collider under development. For an optimal exploitation of its physics potential, CLIC is foreseen to be built and operated in a staged approach with three centre-of-mass energy stages ranging from a few hundred GeV up to 3 TeV. The first stage will focus on precision Standard Model physics, in particular Higgs and top-quark measurements. Read More

2016Apr
Authors: Z. Deng, Y. Li, Y. Wang, Q. Yue, Z. Yang, J. Apostolakis, G. Folger, C. Grefe, V. Ivantchenko, A. Ribon, V. Uzhinskiy, D. Boumediene, C. Carloganu, V. Français, G. Cho, D-W. Kim, S. C. Lee, W. Park, S. Vallecorsa, S. Cauwenbergh, M. Tytgat, A. Pingault, N. Zaganidis, E. Brianne, A. Ebrahimi, K. Gadow, P. Göttlicher, C. Günter, O. Hartbrich, B. Hermberg, A. Irles, F. Krivan, K. Krüger, J. Kvasnicka, S. Lu, B. Lutz, V. Morgunov, C. Neubüser, A. Provenza, M. Reinecke, F. Sefkow, S. Schuwalow, H. L. Tran, E. Garutti, S. Laurien, M. Matysek, M. Ramilli, S. Schroeder, B. Bilki, E. Norbeck, D. Northacker, Y. Onel, S. Chang, A. Khan, D. H. Kim, D. J. Kong, Y. D. Oh, K. Kawagoe, H. Hirai, Y. Sudo, T. Suehara, H. Sumida, T. Yoshioka, E. Cortina Gil, S. Mannai, V. Buridon, C. Combaret, L. Caponetto, R. Eté, G. Garillot, G. Grenier, R. Han, J. C. Ianigro, R. Kieffer, I. Laktineh, N. Lumb, H. Mathez, L. Mirabito, A. Petrukhin, A. Steen, J. Berenguer Antequera, E. Calvo Alamillo, M. -C. Fouz, J. Marin, J. Puerta-Pelayo, A. Verdugo, M. Chadeeva, M. Danilov, M. Gabriel, P. Goecke, C. Kiesling, N. vanderKolk, F. Simon, M. Szalay, S. Bilokin, J. Bonis, P. Cornebise, F. Richard, R. Pöschl, J. Rouëné, A. Thiebault, D. Zerwas, M. Anduze, V. Balagura, K. Belkadhi, V. Boudry, J-C. Brient, R. Cornat, M. Frotin, F. Gastaldi, Y. Haddad, F. Magniette, M. Ruan, M. Rubio-Roy, K. Shpak, H. Videau, D. Yu, S. Callier, S. Conforti di Lorenzo, F. Dulucq, G. Martin-Chassard, Ch. de la Taille, L. Raux, N. Seguin-Moreau, K. Kotera, H. Ono, T. Takeshita, F. Corriveau

The CALICE Semi-Digital Hadron Calorimeter (SDHCAL) technological prototype is a sampling calorimeter using Glass Resistive Plate Chamber detectors with a three-threshold readout as the active medium. This technology is one of the two options proposed for the hadron calorimeter of the International Large Detector for the International Linear Collider. The prototype was exposed to beams of muons, electrons and pions of different energies at the CERN Super Proton Synchrotron. Read More

In special tests, the active layers of the CALICE Digital Hadron Calorimeter prototype, the DHCAL, were exposed to low energy particle beams, without being interleaved by absorber plates. The thickness of each layer corresponded approximately to 0.29 radiation lengths or 0. Read More

2015Sep
Authors: The CALICE collaboration, M. Chefdeville, Y. Karyotakis, J. Repond, J. Schlereth, L. Xia, G. Eigen, J. S. Marshall, M. A. Thomson, D. R. Ward, N. Alipour Tehrani, J. Apostolakis, D. Dannheim, K. Elsener, G. Folger, C. Grefe, V. Ivantchenko, M. Killenberg, W. Klempt, E. van der Kraaij, L. Linssen, A. -I. Lucaci-Timoce, A. Münnich, S. Poss, A. Ribon, P. Roloff, A. Sailer, D. Schlatter, E. Sicking, J. Strube, V. Uzhinskiy, S. Chang, A. Khan, D. H. Kim, D. J. Kong, Y. D. Oh, G. C. Blazey, A. Dyshkant, K. Francis, V. Zutshi, J. Giraud, D. Grondin, J. -Y. Hostachy, E. Brianne, U. Cornett, D. David, G. Falley, K. Gadow, P. Göttlicher, C. Günter, O. Hartbrich, B. Hermberg, A. Irles, S. Karstensen, F. Krivan, K. Krüger, J. Kvasnicka, S. Lu, B. Lutz, S. Morozov, V. Morgunov, C. Neubüser, A. Provenza, M. Reinecke, F. Sefkow, P. Smirnov, M. Terwort, H. L. Tran, A. Vargas-Trevino, E. Garutti, S. Laurien, M. Matysek, M. Ramilli, S. Schröder, K. Briggl, P. Eckert, T. Harion, Y. Munwes, H. -Ch. Schultz-Coulon, W. Shen, R. Stamen, B. Bilki, Y. Onel, K. Kawagoe, H. Hirai, Y. Sudo, T. Suehara, H. Sumida, S. Takada, T. Tomita, T. Yoshioka, M. Wing, E. Calvo Alamillo, M. -C. Fouz, J. Marin, J. Puerta-Pelayo, A. Verdugo, B. Bobchenko, M. Chadeeva, M. Danilov, O. Markin, R. Mizuk, E. Novikov, V. Rusinov, E. Tarkovsky, N. Kirikova, V. Kozlov, P. Smirnov, Y. Soloviev, D. Besson, P. Buzhan, E. Popova, M. Gabriel, C. Kiesling, N. van der Kolk, K. Seidel, F. Simon, C. Soldner, M. Szalay, M. Tesar, L. Weuste, M. S. Amjad, J. Bonis, P. Cornebise, F. Richard, R. Pöschl, J. Rouëné, A. Thiebault, M. Anduze, V. Balagura, V. Boudry, J-C. Brient, J-B. Cizel, R. Cornat, M. Frotin, F. Gastaldi, Y. Haddad, F. Magniette, J. Nanni, S. Pavy, M. Rubio-Roy, K. Shpak, T. H. Tran, H. Videau, D. Yu, S. Callier, S. Conforti di Lorenzo, F. Dulucq, J. Fleury, G. Martin-Chassard, Ch. de la Taille, L. Raux, N. Seguin-Moreau, J. Cvach, P. Gallus, M. Havranek, M. Janata, M. Kovalcuk, J. Kvasnicka, D. Lednicky, M. Marcisovsky, I. Polak, J. Popule, L. Tomasek, M. Tomasek, P. Ruzicka, P. Sicho, J. Smolik, V. Vrba, J. Zalesak, S. Ieki, Y. Kamiya, W. Ootani, N. Shibata, S. Chen, D. Jeans, S. Komamiya, C. Kozakai, H. Nakanishi, M. Götze, J. Sauer, S. Weber, C. Zeitnitz

We present a study of showers initiated by electrons, pions, kaons, and protons with momenta from 15 GeV to 150 GeV in the highly granular CALICE scintillator-tungsten analogue hadronic calorimeter. The data were recorded at the CERN Super Proton Synchrotron in 2011. The analysis includes measurements of the calorimeter response to each particle type as well as measurements of the energy resolution and studies of the longitudinal and radial shower development for selected particles. Read More

The future Compact Linear Collider (CLIC) offers a possibility for a rich precision physics programme, in particular in the Higgs sector through the energy staging. This is the first paper addressing the measurement of the Standard Model Higgs boson decay into two muons at 1.4 TeV CLIC. Read More

The potential for the measurement of the branching ratio of the Standard Model-like Higgs boson decay into a mu+mu- pair at 1.4 TeV CLIC is analysed. The study is performed using the fully simulated CLIC_ILD detector concept, taking into consideration all the relevant physics and the beam-induced backgrounds. Read More

2014Apr
Authors: C. Adloff1, J. -J. Blaising2, M. Chefdeville3, C. Drancourt4, R. Gaglione5, N. Geffroy6, Y. Karyotakis7, I. Koletsou8, J. Prast9, G. Vouters J. Repond10, J. Schlereth11, L. Xia E. Baldolemar12, J. Li13, S. T. Park14, M. Sosebee15, A. P. White16, J. Yu17, G. Eigen18, M. A. Thomson19, D. R. Ward20, D. Benchekroun21, A. Hoummada22, Y. Khoulaki J. Apostolakis23, S. Arfaoui24, M. Benoit25, D. Dannheim26, K. Elsener27, G. Folger28, C. Grefe29, V. Ivantchenko30, M. Killenberg31, W. Klempt32, E. van der Kraaij33, L. Linssen34, A. -I. Lucaci-Timoce35, A. Münnich36, S. Poss37, A. Ribon38, P. Roloff39, A. Sailer40, D. Schlatter41, E. Sicking42, J. Strube43, V. Uzhinskiy44, C. Carloganu45, P. Gay46, S. Manen47, L. Royer48, U. Cornett49, D. David50, A. Ebrahimi51, G. Falley52, N. Feege53, K. Gadow54, P. Göttlicher55, C. Günter56, O. Hartbrich57, B. Hermberg58, S. Karstensen59, F. Krivan60, K. Krüger61, S. Lu62, B. Lutz63, S. Morozov64, V. Morgunov65, C. Neubüser66, M. Reinecke67, F. Sefkow68, P. Smirnov69, M. Terwort70, A. Fagot71, M. Tytgat72, N. Zaganidis73, J. -Y. Hostachy74, L. Morin75, E. Garutti76, S. Laurien77, I. Marchesini78, M. Matysek79, M. Ramilli80, K. Briggl81, P. Eckert82, T. Harion83, H. -Ch. Schultz-Coulon84, W. Shen85, R. Stamen86, S. Chang87, A. Khan88, D. H. Kim89, D. J. Kong90, Y. D. Oh91, B. Bilki92, E. Norbeck93, D. Northacker94, Y. Onel95, G. W. Wilson96, K. Kawagoe97, Y. Miyazaki98, Y. Sudo99, H. Ueno100, T. Yoshioka101, P. D. Dauncey102, E. Cortina Gil103, S. Mannai104, G. Baulieu105, P. Calabria106, L. Caponetto107, C. Combaret108, R. Della Negra109, R. Ete110, G. Grenier111, R. Han112, J-C. Ianigro113, R. Kieffer114, I. Laktineh115, N. Lumb116, H. Mathez117, L. Mirabito118, A. Petrukhin119, A. Steen120, W. Tromeur121, M. Vander Donckt122, Y. Zoccarato J. Berenguer Antequera123, E. Calvo Alamillo124, M. -C. Fouz125, J. Puerta-Pelayo126, F. Corriveau127, B. Bobchenko128, M. Chadeeva129, M. Danilov130, A. Epifantsev131, O. Markin132, R. Mizuk133, E. Novikov134, V. Rusinov135, E. Tarkovsky136, V. Kozlov137, Y. Soloviev138, D. Besson139, P. Buzhan140, A. Ilyin141, V. Kantserov142, V. Kaplin143, E. Popova144, V. Tikhomirov145, M. Gabriel146, C. Kiesling147, K. Seidel148, F. Simon149, C. Soldner150, M. Szalay151, M. Tesar152, L. Weuste153, M. S. Amjad154, J. Bonis155, S. Conforti di Lorenzo156, P. Cornebise157, J. Fleury158, T. Frisson159, N. van der Kolk160, F. Richard161, R. Pöschl162, J. Rouene163, M. Anduze164, V. Balagura165, E. Becheva166, V. Boudry167, J-C. Brient168, R. Cornat169, M. Frotin170, F. Gastaldi171, E. Guliyev172, Y. Haddad173, F. Magniette174, M. Ruan175, T. H. Tran176, H. Videau177, S. Callier178, F. Dulucq179, G. Martin-Chassard180, Ch. de la Taille181, L. Raux182, N. Seguin-Moreau183, J. Zacek184, J. Cvach185, P. Gallus186, M. Havranek187, M. Janata188, J. Kvasnicka189, D. Lednicky190, M. Marcisovsky191, I. Polak192, J. Popule193, L. Tomasek194, M. Tomasek195, P. Ruzicka196, P. Sicho197, J. Smolik198, V. Vrba199, J. Zalesak200, . Belhorma201, H. Ghazlane202, K. Kotera203, H. Ono204, T. Takeshita205, S. Uozumi206, J. S. Chai207, H. S. Song208, S. H. Lee209, M. Götze210, J. Sauer211, S. Weber212, C. Zeitnitz213
Affiliations: 1The CALICE Collaboration, 2The CALICE Collaboration, 3The CALICE Collaboration, 4The CALICE Collaboration, 5The CALICE Collaboration, 6The CALICE Collaboration, 7The CALICE Collaboration, 8The CALICE Collaboration, 9The CALICE Collaboration, 10The CALICE Collaboration, 11The CALICE Collaboration, 12The CALICE Collaboration, 13The CALICE Collaboration, 14The CALICE Collaboration, 15The CALICE Collaboration, 16The CALICE Collaboration, 17The CALICE Collaboration, 18The CALICE Collaboration, 19The CALICE Collaboration, 20The CALICE Collaboration, 21The CALICE Collaboration, 22The CALICE Collaboration, 23The CALICE Collaboration, 24The CALICE Collaboration, 25The CALICE Collaboration, 26The CALICE Collaboration, 27The CALICE Collaboration, 28The CALICE Collaboration, 29The CALICE Collaboration, 30The CALICE Collaboration, 31The CALICE Collaboration, 32The CALICE Collaboration, 33The CALICE Collaboration, 34The CALICE Collaboration, 35The CALICE Collaboration, 36The CALICE 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CALICE Collaboration, 73The CALICE Collaboration, 74The CALICE Collaboration, 75The CALICE Collaboration, 76The CALICE Collaboration, 77The CALICE Collaboration, 78The CALICE Collaboration, 79The CALICE Collaboration, 80The CALICE Collaboration, 81The CALICE Collaboration, 82The CALICE Collaboration, 83The CALICE Collaboration, 84The CALICE Collaboration, 85The CALICE Collaboration, 86The CALICE Collaboration, 87The CALICE Collaboration, 88The CALICE Collaboration, 89The CALICE Collaboration, 90The CALICE Collaboration, 91The CALICE Collaboration, 92The CALICE Collaboration, 93The CALICE Collaboration, 94The CALICE Collaboration, 95The CALICE Collaboration, 96The CALICE Collaboration, 97The CALICE Collaboration, 98The CALICE Collaboration, 99The CALICE Collaboration, 100The CALICE Collaboration, 101The CALICE Collaboration, 102The CALICE Collaboration, 103The CALICE Collaboration, 104The CALICE Collaboration, 105The CALICE Collaboration, 106The CALICE Collaboration, 107The CALICE 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142The CALICE Collaboration, 143The CALICE Collaboration, 144The CALICE Collaboration, 145The CALICE Collaboration, 146The CALICE Collaboration, 147The CALICE Collaboration, 148The CALICE Collaboration, 149The CALICE Collaboration, 150The CALICE Collaboration, 151The CALICE Collaboration, 152The CALICE Collaboration, 153The CALICE Collaboration, 154The CALICE Collaboration, 155The CALICE Collaboration, 156The CALICE Collaboration, 157The CALICE Collaboration, 158The CALICE Collaboration, 159The CALICE Collaboration, 160The CALICE Collaboration, 161The CALICE Collaboration, 162The CALICE Collaboration, 163The CALICE Collaboration, 164The CALICE Collaboration, 165The CALICE Collaboration, 166The CALICE Collaboration, 167The CALICE Collaboration, 168The CALICE Collaboration, 169The CALICE Collaboration, 170The CALICE Collaboration, 171The CALICE Collaboration, 172The CALICE Collaboration, 173The CALICE Collaboration, 174The CALICE Collaboration, 175The CALICE Collaboration, 176The CALICE Collaboration, 177The CALICE Collaboration, 178The CALICE Collaboration, 179The CALICE Collaboration, 180The CALICE Collaboration, 181The CALICE Collaboration, 182The CALICE Collaboration, 183The CALICE Collaboration, 184The CALICE Collaboration, 185The CALICE Collaboration, 186The CALICE Collaboration, 187The CALICE Collaboration, 188The CALICE Collaboration, 189The CALICE Collaboration, 190The CALICE Collaboration, 191The CALICE Collaboration, 192The CALICE Collaboration, 193The CALICE Collaboration, 194The CALICE Collaboration, 195The CALICE Collaboration, 196The CALICE Collaboration, 197The CALICE Collaboration, 198The CALICE Collaboration, 199The CALICE Collaboration, 200The CALICE Collaboration, 201The CALICE Collaboration, 202The CALICE Collaboration, 203The CALICE Collaboration, 204The CALICE Collaboration, 205The CALICE Collaboration, 206The CALICE Collaboration, 207The CALICE Collaboration, 208The CALICE Collaboration, 209The CALICE Collaboration, 210The CALICE Collaboration, 211The CALICE Collaboration, 212The CALICE Collaboration, 213The CALICE Collaboration

The intrinsic time structure of hadronic showers influences the timing capability and the required integration time of hadronic calorimeters in particle physics experiments, and depends on the active medium and on the absorber of the calorimeter. With the CALICE T3B experiment, a setup of 15 small plastic scintillator tiles read out with Silicon Photomultipliers, the time structure of showers is measured on a statistical basis with high spatial and temporal resolution in sampling calorimeters with tungsten and steel absorbers. The results are compared to GEANT4 (version 9. Read More

The Compact Linear Collider (CLIC) is a concept for a future $e^{+}e^{-}$ linear collider with a center-of-mass energy of up to 3 TeV. The design of a CLIC experiment is driven by the requirements related to the physics goals, as well as by the experimental conditions. For example, the short time between two bunch crossings of 0. Read More

2013Nov
Authors: C. Adloff, J. -J. Blaising, M. Chefdeville, C. Drancourt, R. Gaglione, N. Geffroy, Y. Karyotakis, I. Koletsou, J. Prast, G. Vouters, J. Repond, J. Schlereth, J. Smith, L. Xia, E. Baldolemar, J. Li, S. T. Park, M. Sosebee, A. P. White, J. Yu, G. Eigen, M. A. Thomson, D. R. Ward, D. Benchekroun, A. Hoummada, Y. Khoulaki, J. Apostolakis, D. Dannheim, A. Dotti, K. Elsener, G. Folger, C. Grefe, V. Ivantchenko, M. Killenberg, W. Klempt, E. van der Kraaij, C. B. Lam, L. Linssen, A. -I. Lucaci-Timoce, A. Muennich, S. Poss, A. Ribon, A. Sailer, D. Schlatter, J. Strube, V. Uzhinskiy, C. Carloganu, P. Gay, S. Manen, L. Royer, M. Tytgat, N. Zaganidis, G. C. Blazey, A. Dyshkant, J. G. R. Lima, V. Zutshi, J. -Y. Hostachy, L. Morin, U. Cornett, D. David, A. Ebrahimi, G. Falley, N. Feege, K. Gadow, P. Goettlicher, C. Guenter, O. Hartbrich, B. Hermberg, S. Karstensen, F. Krivan, K. Krueger, S. Lu, B. Lutz, S. Morozov, V. Morgunov, C. Neubueser, M. Reinecke, F. Sefkow, P. Smirnov, M. Terwort, E. Garutti, S. Laurien, I. Marchesini, M. Matysek, M. Ramilli, K. Briggl, P. Eckert, T. Harion, H. -Ch. Schultz-Coulon, W. Shen, R. Stamen, B. Bilki, E. Norbeck, D. Northacker, Y. Onel, G. W. Wilson, K. Kawagoe, Y. Sudo, T. Yoshioka, P. D. Dauncey, M. Wing, F. Salvatore, E. Cortina Gil, S. Mannai, G. Baulieu, P. Calabria, L. Caponetto, C. Combaret, R. Della Negra, G. Grenier, R. Han, J-C. Ianigro, R. Kieffer, I. Laktineh, N. Lumb, H. Mathez, L. Mirabito, A. Petrukhin, A. Steen, W. Tromeur, M. Vander Donckt, Y. Zoccarato, E. Calvo Alamillo, M. -C. Fouz, J. Puerta-Pelayo, F. Corriveau, B. Bobchenko, M. Chadeeva, M. Danilov, A. Epifantsev, O. Markin, R. Mizuk, E. Novikov, V. Popov, V. Rusinov, E. Tarkovsky, N. Kirikova, V. Kozlov, P. Smirnov, Y. Soloviev, D. Besson, P. Buzhan, A. Ilyin, V. Kantserov, V. Kaplin, A. Karakash, E. Popova, V. Tikhomirov, C. Kiesling, K. Seidel, F. Simon, C. Soldner, M. Szalay, M. Tesar, L. Weuste, M. S. Amjad, J. Bonis, S. Callier, S. Conforti di Lorenzo, P. Cornebise, Ph. Doublet, F. Dulucq, J. Fleury, T. Frisson, N. van der Kolk, H. Li, G. Martin-Chassard, F. Richard, Ch. de la Taille, R. Poeschl, L. Raux, J. Rouene, N. Seguin-Moreau, M. Anduze, V. Balagura, V. Boudry, J-C. Brient, R. Cornat, M. Frotin, F. Gastaldi, E. Guliyev, Y. Haddad, F. Magniette, G. Musat, M. Ruan, T. H. Tran, H. Videau, B. Bulanek, J. Zacek, J. Cvach, P. Gallus, M. Havranek, M. Janata, J. Kvasnicka, D. Lednicky, M. Marcisovsky, I. Polak, J. Popule, L. Tomasek, M. Tomasek, P. Ruzicka, P. Sicho, J. Smolik, V. Vrba, J. Zalesak, B. Belhorma, H. Ghazlane, K. Kotera, T. Takeshita, S. Uozumi, S. Chang, A. Khan, D. H. Kim, D. J. Kong, Y. D. Oh, M. Goetze, J. Sauer, S. Weber, C. Zeitnitz

Lepton colliders are considered as options to complement and to extend the physics programme at the Large Hadron Collider. The Compact Linear Collider (CLIC) is an $e^+e^-$ collider under development aiming at centre-of-mass energies of up to 3 TeV. For experiments at CLIC, a hadron sampling calorimeter with tungsten absorber is proposed. Read More

2013Jul
Authors: Halina Abramowicz, Angel Abusleme, Konstatin Afanaciev, Gideon Alexander, Niloufar Alipour Tehrani, Oscar Alonso, Kristoffer K. Andersen, Samir Arfaoui, Csaba Balazs, Tim Barklow, Marco Battaglia, Mathieu Benoit, Burak Bilki, Jean-Jacques Blaising, Mark Boland, Marça Boronat, Ivanka Božović Jelisavčić, Philip Burrows, Maximilien Chefdeville, Roberto Contino, Dominik Dannheim, Marcel Demarteau, Marco Aurelio Diaz Gutierrez, Angel Diéguez, Jorge Duarte Campderros, Gerald Eigen, Konrad Elsener, Dan Feldman, Uli Felzmann, Mirosław Firlej, Elena Firu, Tomasz Fiutowski, Kurt Francis, Frank Gaede, Ignacio García García, Veta Ghenescu, Gian Giudice, Norman Graf, Christian Grefe, Christophe Grojean, Rick S. Gupta, Michael Hauschild, Helga Holmestad, Marek Idzik, Christian Joram, Sergey Kananov, Yannis Karyotakis, Martin Killenberg, Wolfgang Klempt, Sabine Kraml, Beata Krupa, Szymon Kulis, Tomáš Laštovička, Greg LeBlanc, Aharon Levy, Itamar Levy, Lucie Linssen, Angela Lucaci Timoce, Strahinja Lukić, Vladimir Makarenko, John Marshall, Victoria Martin, Rune E. Mikkelsen, Gordana Milutinović-Dumbelović, Akiya Miyamoto, Klaus Mönig, Gudrid Moortgat-Pick, Jakub Moroń, Astrid Münnich, Alina Neagu, Mila Pandurović, Duccio Pappadopulo, Bogdan Pawlik, Werner Porod, Stéphane Poss, Titi Preda, Roger Rassool, Ricardo Rattazzi, Sophie Redford, Jose Repond, Sabine Riemann, Aidan Robson, Philipp Roloff, Eduardo Ros, Jonatan Rosten, Alberto Ruiz-Jimeno, Heidi Rzehak, André Sailer, Dieter Schlatter, Daniel Schulte, Felix Sefkow, Katja Seidel, Nikolai Shumeiko, Eva Sicking, Frank Simon, Jacob Smith, Christian Soldner, Steinar Stapnes, Jan Strube, Taikan Suehara, Krzysztof Świentek, Marco Szalay, Tomohiko Tanabe, Michal Tesař, Andrea Thamm, Mark Thomson, Juan Trenado Garcia, Ulrik I. Uggerhøj, Erik van der Kraaij, Iván Vila, Eva Vilella, Miguel Angel Villarejo, Marcelo Alonso Vogel Gonzalez, Marcel Vos, Nigel Watson, Harry Weerts, James D. Wells, Lars Weuste, Tobias N. Wistisen, Kent Wootton, Lei Xia, Leszek Zawiejski, Ion-Sorin Zgura

This paper summarizes the physics potential of the CLIC high-energy e+e- linear collider. It provides input to the Snowmass 2013 process for the energy-frontier working groups on The Higgs Boson (HE1), Precision Study of Electroweak Interactions (HE2), Fully Understanding the Top Quark (HE3), as well as The Path Beyond the Standard Model -- New Particles, Forces, and Dimensions (HE4). It is accompanied by a paper describing the CLIC accelerator study, submitted to the Frontier Capabilities group of the Snowmass process. Read More

The investigation of the properties of the Higgs boson, especially a test of the predicted linear dependence of the branching ratios on the mass of the final state is going to be an integral part of the physics program at colliders at the energy frontier for the foreseeable future. The large Higgs boson production cross section at a 3TeV CLIC machine allows for a precision measurement of the Higgs branching ratios. The cross section times branching ratio of the decays H->bb, H->cc and H->{\mu}{\mu} of a Standard Model Higgs boson with a mass of 120 GeV can be measured with a statistical uncertainty of 0. Read More

The Higgs boson is the most anticipated discovery at the LHC, which can only partially explore its true nature. Thus one of the most compelling arguments to build a future linear collider is to investigate properties of the Higgs boson, especially to test the predicted linear dependence of the branching ratios on the mass of the final state. At a 3TeV CLIC machine the Higgs boson production cross section is relatively large and allows for a precision measurement of the Higgs branching ratio to pairs of b and c quarks, and even to muons. Read More

The investigation of the properties of a Higgs boson, especially a test of the predicted linear dependence of the branching ratios on the mass of the final state, is currently one of the most compelling arguments for building a linear collider. We demonstrate that the large Higgs boson production cross section at a 3 TeV CLIC machine allows for a precision measurement of the Higgs branching ratios. The cross section times branching ratio of the decays H \rightarrow b^{-}b, H \rightarrow cc^{-} and H \rightarrow {\mu}{\mu} can be measured with a statistical uncertainty of 0. Read More

2012Jan
Authors: J. Aguilar, P. Ambalathankandy, T. Fiutowski, M. Idzik, Sz. Kulis, D. Przyborowski, K. Swientek, A. Bamberger, M. Köhli, M. Lupberger, U. Renz, M. Schumacher, Andreas Zwerger, A. Calderone, D. G. Cussans, H. F. Heath, S. Mandry, R. F. Page, J. J. Velthuis, D. Attié, D. Calvet, P. Colas, X. Coppolani, Y. Degerli, E. Delagnes, M. Gelin, I. Giomataris, P. Lutz, F. Orsini, M. Rialot, F. Senée, W. Wang, J. Alozy, J. Apostolakis, P. Aspell, F. Bergsma, M. Campbell, F. Formenti, H. Franca Santos, E. Garcia Garcia, M. de Gaspari, P. -A. Giudice, Ch. Grefe, V. Grichine, M. Hauschild, V. Ivantchenko, A. Kehrli, K. Kloukinas, L. Linssen, X. Llopart Cudie, A. Marchioro, L. Musa, A. Ribon, G. Trampitsch, V. Uzhinskiy, M. Anduze, E. Beyer, A. Bonnemaison, V. Boudry, J. -C. Brient, A. Cauchois, C. Clerc, R. Cornat, M. Frotin, F. Gastaldi, C. Jauffret, D. Jeans, A. Karar, A. Mathieu, P. Mora de Freitas, G. Musat, A. Rougé, M. Ruan, J. -C. Vanel, H. Videau, A. Besson, G. Claus. R. de Masi, G. Doziere, W. Dulinski, M. Goffe, A. Himmi, Ch. Hu-Guo, F. Morel, I. Valin, M. Winter, J. Bonis, S. Callier, P. Cornebise, F. Dulucq, M. Faucci Giannelli, J. Fleury, G. Guilhem, G. Martin-Chassard, Ch. de la Taille, R. Pöschl, L. Raux, N. Seguin-Moreau, F. Wicek, M. Benyamna, J. Bonnard, C. Cârloganu, F. Fehr, P. Gay, S. Mannen, L. Royer, A. Charpy, W. Da Silva, J. David, M. Dhellot, D. Imbault, P. Ghislain, F. Kapusta, T. Hung Pham, A. Savoy-Navarro, R. Sefri, D. Dzahini, J. Giraud, D. Grondin, J. -Y. Hostachy, L. Morin, D. Bassignana, G. Pellegrini, M. Lozano, D. Quirion, M. Fernandez, R. Jaramillo, F. J. Munoz, I. Vila, Z. Dolezal, Z. Drasal, P. Kodys, P. Kvasnicka, S. Aplin, O. Bachynska, T. Behnke, J. Behr, K. Dehmelt, J. Engels, K. Gadow, F. Gaede, E. Garutti, P. Göttlicher, I. -M. Gregor, T. Haas, H. Henschel, U. Koetz, W. Lange, V. Libov, W. Lohmann, B. Lutz, J. Mnich, C. Muhl, M. Ohlerich, N. Potylitsina-Kube, V. Prahl, M. Reinecke, P. Roloff, Ch. Rosemann, Igor Rubinski, P. Schade, S. Schuwalov, F. Sefkow, M. Terwort, R. Volkenborn, J. Kalliopuska, P. Mehtaelae, R. Orava, N. van Remortel, J. Cvach, M. Janata, J. Kvasnicka, M. Marcisovsky, I. Polak, P. Sicho, J. Smolik, V. Vrba, J. Zalesak, T. Bergauer, M. Dragicevic, M. Friedl, S. Haensel, C. Irmler, W. Kiesenhofer, M. Krammer, M. Valentan, L. Piemontese, A. Cotta-Ramusino, A. Bulgheroni, M. Jastrzab, M. Caccia, V. Re, L. Ratti, G. Traversi, J. -P. Dewulf, X. Janssen, G. De Lentdecker, Y. Yang, L. Bryngemark, P. Christiansen, P. Gross, L. Jönsson, M. Ljunggren, B. Lundberg, U. Mjörnmark, A. Oskarsson, T. Richert, E. Stenlund, L. Österman, S. Rummel, R. Richter, L. Andricek, J. Ninkovich, Ch. Koffmane, H. -G. Moser, V. Boisvert, B. Green, M. G. Green, A. Misiejuk, T. Wu, Y. Bilevych, V. M. Blanco Carballo, M. Chefdeville, L. de Nooij, M. Fransen, F. Hartjes, H. van der Graaf, J. Timmermans, H. Abramowicz, Y. Ben-Hamu, I. Jikhleb, S. Kananov, A. Levy, I. Levy, I. Sadeh, R. Schwartz, A. Stern, M. J. Goodrick, L. B. A. Hommels, R. Shaw. D. R. Ward, W. Daniluk, E. Kielar, J. Kotula, A. Moszczynski, K. Oliwa, B. Pawlik, W. Wierba, L. Zawiejski, D. S. Bailey, M. Kelly, G. Eigen, Ch. Brezina, K. Desch, J. Furletova, J. Kaminski, M. Killenberg, F. Köckner, T. Krautscheid, H. Krüger, L. Reuen, P. Wienemann, R. Zimmermann, S. Zimmermann, V. Bartsch, M. Postranecky, M. Warren, M. Wing, E. Corrin, D. Haas, M. Pohl, R. Diener, P. Fischer, I. Peric, A. Kaukher, O. Schäfer, H. Schröder, R. Wurth, A. F. Zarnecki

The EUDET-project was launched to create an infrastructure for developing and testing new and advanced detector technologies to be used at a future linear collider. The aim was to make possible experimentation and analysis of data for institutes, which otherwise could not be realized due to lack of resources. The infrastructure comprised an analysis and software network, and instrumentation infrastructures for tracking detectors as well as for calorimetry. Read More