The R 3 B Collaboration Brazil University of Sao Paulo: Alinka Lepine-Szily Canada Saint Mary’s University Halifax: Rituparna Kanungo TRIUMF Vancouver: Reiner Krücken China Institute of Modern Physics Lanzhou: Ruofu Chen, Songlin Li, Hushan Xu, Yu-Hu Zhang Denmark Arhus University: Dmitri Fedorov, Hans Fynbo, Aksel Jensen, Karsten Riisager VTT: Simo Eränen, Juha Kalliopuska Finland France CEA/DAM Bruyères-le-Châtel: Farouk Aksouh, Audrey Chatillon, Julien Taieb CEA/DSM/IRFU Saclay: Alain Boudard, Diane Dore, Bernard Gastineau, Wolfram Korten, Philippe Legou, Sylvie Leray, Stefano Panebianco GANIL: David Boilley, Wolfgang Mittig, Fanny Rejmund, Patricia Roussel-Chomaz, Herve Savajols, Christelle Schmitt IPN Orsay: Bernard Genolini 2
Germany EMMI and FIAS: Enrico Fiori, Bastian Löher, Deniz Savran GSI Darmstadt: Yuliya Aksyutina, Denis Bertini, Konstanze Boretzky, Peter Egelhof, Hans Emling, Hans Feldmeier, Hans Geissel, Jürgen Gerl, Kathrin Goebel, Magdalena Górska, Jörg Hehner, Michael Heil, Jan Hoffmann, Günter Ickert, Aleksandra Kelic-Heil, Ivan Kojouharov, Nikolaus Kurz, Karl-Heinz Langanke, Yvonne Leifels, Thomas Neff, Chiara Nociforo, Maria Valentina Ricciardi, Dominic Rossi, Thomas Roth, Takehiko Saito, Karl-Heinz Schmidt, Haik Simon, Klaus Sümmerer, Wolfgang Trautmann, Helmut Weick, Martin Winkler Helmholtz-Zentrum Dresden-Rossendorf: Daniel Bemmerer, Zoltan Elekes, Arnd Junghans, Mathias Kempe, Manfred Sobiella, Daniel Stach, Andreas Wagner, Jörn Wüstenfeld, Dmitry Yakorev TU Darmstadt: Leyla Atar, Thomas Aumann, Timo Bloch, Christoph Caesar, Joachim Enders, Diego Gonzalez-Diaz, Marcel Heine, Matthias Holl, Alexander Ignatov, Oleg Kiselev, Dmytro Kresan, Thorsten Kröll, Alina Movsesyan, Manfred Mutterer, Valerii Panin, Stefanos Paschalis, Marina Petri, Norbert Pietralla, Achim Richter, Heiko Scheit, Mirko von Schmid, Linda Schnorrenberger, Philipp Schrock, Stefan Typel, Vasily Volkov, Felix Wamers TU Dresden: Thomas Cowan, Marko Röder, Kai Zuber TU Munich: Michael Bendel, Michael Böhmer, Thomas Faestermann, Roman Gernhäuser, Walter Henning, Reiner Krücken, Tudi Le Bleis, Olga Lepyoshkina, Max Winkel, Sonja Winkler University of Cologne: Jannis Endres, Andreas Hennig, Vassili Maroussov, Lars Netterdon, Peter Reiter, Andreas Zilges University of Frankfurt: Sebastian Altstadt, Olga Ershova, Christoph Langer, Christian Müntz, Ralf Plag, René Reifarth, Kerstin Sonnabend, Meiko Volknandt, Christine Wimmer University of Gießen: Horst Lenske Unversity of Mainz: Jens Volker Kratz Hungary ATOMKI: Margit Csatlós, Zoltán Elekes, Zsolt Fülöp, János Gulyás, Attila Krasznahorkay, László Stuhl, János Timár, Tamás Tornyi University of Budapest: Ákos Horváth 3
- Page 1: FAIR/NUSTAR/R 3 B/TDR NeuLAND Techn
- Page 5 and 6: INR Moscow: Alexander Botvina Russi
- Page 7 and 8: Contents Executive Summary 11 1. In
- Page 9: B.7. MRPC Solution using Glass as C
- Page 12 and 13: Apart from the excellent energy res
- Page 14 and 15: processes in the universe, such as
- Page 16 and 17: decaying into 24 O plus 4 neutrons
- Page 19 and 20: 2. Physics Scenarios: Requirements
- Page 21 and 22: e studied at R 3 B at FAIR include
- Page 23 and 24: all theoretical calculations predic
- Page 25 and 26: at the surface of the nucleus. The
- Page 27 and 28: the evolution of fission channels (
- Page 29 and 30: 3. Summary of NeuLAND Prototype Res
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- Page 33 and 34: Figure 3.4.: Shown is the time reso
- Page 35 and 36: 4. Monte Carlo Simulations Within t
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- Page 39 and 40: GEANT3 interface. Here, we compare
- Page 41 and 42: Counts 1000 900 800 700 600 500 400
- Page 43 and 44: counts 5 10 4 10 3 10 2 10 10 LAND
- Page 45 and 46: incident neutron fully active detec
- Page 47 and 48: investigated. Three values for the
- Page 49 and 50: spectrum, absorption length, refrac
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Since, as discussed above, several
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events 800 600 400 200 0 0 200 400
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clusters N 100 50 0 0 500 1000 1500
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In the following section we discuss
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events 15000 10000 5000 input outpu
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events 2000 1500 1000 500 σ = 15 k
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5. Technical Specifications and Des
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construction, or for subsequent rep
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positioning of 50 submodules mounti
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Figure 5.6.: Detector frame with fi
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5.4. Peripheral Systems 5.4.1. Read
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Figure 5.12.: The photo shows the T
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6. Radiation Environment and Safety
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8. Calibration 8.1. Calibration wit
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Figure 8.3.: ToF distribution in 10
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Figure 8.4.: Event display for seve
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10. Installation procedure, its Tim
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11. Cost and Funding 11.1. Cost Est
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The timeline for milestone 1 includ
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96 2. Sample Tests Random samples o
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PNPI St. Petersburg: G.D. Alkhazov,
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HV 1.$ mm 2$ mm 0+$1-2)-2'.%/ 5%4'.
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Beamline Be exit window P 6 P 3 P 4
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B.3. Design Issues Addressed with 4
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Time [ns] Counts 41 40 39 2200 2000
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Efficiency 100 80 60 40 20 0 7.5 8
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200 AMeV, Erel = 100 keV emitted %
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B.7. MRPC Solution using Glass as C
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114
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[Bot-04] S. Botvina andI.N. Mishust
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[Lip-03] C. Lippmann, PhD Thesis, U