Your search keyword '"Vincke H."' showing total 290 results

1. Design and early operation of a new-generation internal beam dump for CERN's Super Proton Synchrotron

Author

Francia, A. Romero, Marcone, A. Perillo, Pianese, S., Andersen, K., Izquierdo, G. Arnau, Briz, J. A., Perez, D. Carbajo, Carlier, E., Coiffet, T., Esposito, L. S., Grenard, J. L., Grenier, D., Humbert, J., Kershaw, K., Lendaro, J., Rolo, A. Ortega, Scibor, K., Senajova, D., Sgobba, S., Sharp, C., Steyaert, D., Velotti, F. M., Vincke, H., Vlachoudis, V., and Calviani, M.

Subjects

Physics - Accelerator Physics, High Energy Physics - Experiment, Nuclear Experiment, Physics - Instrumentation and Detectors

Abstract

The Super Proton Synchrotron (SPS) is the last stage in the injector chain for CERN's Large Hadron Collider, and it also provides proton and ion beams for several fixed-target experiments. The SPS has been in operation since 1976, and it has been upgraded over the years. For the SPS to operate safely, its internal beam dump must be able to repeatedly absorb the energy of the circulating beams without sustaining damage that would affect its function. The latest upgrades of the SPS led to the requirement for its beam dump to absorb proton beams with a momentum spectrum from 14 to 450~GeV/$c$ and an average beam power up to $\sim$270~kW. This paper presents the technical details of a new design of SPS beam dump that was installed in one of the long straight sections of the SPS during the 2019--2020 shutdown of CERN's accelerator complex. This new beam dump has been in operation since May 2021, and it is foreseen that it will operate with a lifetime of 20~years. The key challenges in the design of the beam dump were linked to the high levels of thermal energy to be dissipated -- to avoid overheating and damage to the beam dump itself -- and high induced levels of radiation, which have implications for personnel access to monitor the beam dump and repair any problems occurring during operation. The design process therefore included extensive thermomechanical finite-element simulations of the beam-dump core and its cooling system's response to normal operation and worst-case scenarios for beam dumping. To ensure high thermal conductivity between the beam-dump core and its water-cooling system, hot isostatic pressing techniques were used in its manufacturing process. A comprehensive set of instrumentation was installed in the beam dump to monitor it during operation and to cross-check the numerical models with operational feedback., Comment: 20 pages, 36 figures, submitted to Phys. Rev. Accel. Beams

Published

2023

2. A Long-Baseline Atom Interferometer at CERN: Conceptual Feasibility Study

Author

Arduini, G., Badurina, L., Balazs, K., Baynham, C., Buchmueller, O., Buzio, M., Calatroni, S., Corso, J. -P., Ellis, J., Gaignant, Ch., Guinchard, M., Hakulinen, T., Hobson, R., Infantino, A., Lafarge, D., Langlois, R., Marcel, C., Mitchell, J., Parodi, M., Pentella, M., Valuch, D., and Vincke, H.

Subjects

Physics - Atomic Physics, Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Experiment, Quantum Physics

Abstract

We present results from exploratory studies, supported by the Physics Beyond Colliders (PBC) Study Group, of the suitability of a CERN site and its infrastructure for hosting a vertical atom interferometer (AI) with a baseline of about 100 m. We first review the scientific motivations for such an experiment to search for ultralight dark matter and measure gravitational waves, and then outline the general technical requirements for such an atom interferometer, using the AION-100 project as an example. We present a possible CERN site in the PX46 access shaft to the Large Hadron Collider (LHC), including the motivations for this choice and a description of its infrastructure. We then assess its compliance with the technical requirements of such an experiment and what upgrades may be needed. We analyse issues related to the proximity of the LHC machine and its ancillary hardware and present a preliminary safety analysis and the required mitigation measures and infrastructure modifications. In conclusion, we identify primary cost drivers and describe constraints on the experimental installation and operation schedules arising from LHC operation. We find no technical obstacles: the CERN site is a very promising location for an AI experiment with a vertical baseline of about 100 m., Comment: 51 pages, 39 figures, version with higher resolution figures available from https://cds.cern.ch/record/2851946/

Published

2023

3. Letter of Intent: the NA60+ experiment

Author

Ahdida, C., Alocco, G., Antinori, F., Arba, M., Aresti, M., Arnaldi, R., Roldan, A. Baratto, Beole, S., Beraudo, A., Bernhard, J., Bianchi, L., Borysova, M., Bressler, S., Bufalino, S., Casula, E., Cicalo, C., Coli, S., Cortese, P., Dainese, A., Danielsson, H., De Falco, A., Dehmelt, K., Drees, A., Ferretti, A., Fionda, F., Gagliardi, M., Gerbershagen, A., Geurts, F., Greco, V., Li, W., Lombardo, M. P., Marras, D., Masera, M., Masoni, A., Mazzaschi, F., Micheletti, L., Mirasola, L., Mentink, M., Mereu, P., Milov, A., Mulliri, A., Musa, L., Oppedisano, C., Paul, B., Pennisi, M., Plumari, S., Prino, F., Puccio, M., Puggioni, C., Rapp, R., Ravinovich, I., Rossi, A., Sarritzu, V., Schmidt, B., Scomparin, E., Siddhanta, S., Shahoyan, R., Tuveri, M., Uras, A., Usai, G., Vincke, H., and Vorobyev, I.

Subjects

Nuclear Experiment, Physics - Instrumentation and Detectors

Abstract

We propose a new fixed-target experiment for the study of electromagnetic and hard probes of the Quark-Gluon Plasma (QGP) in heavy-ion collisions at the CERN SPS. The experiment aims at performing measurements of the dimuon spectrum from threshold up to the charmonium region, and of hadronic decays of charm and strange hadrons. It is based on a muon spectrometer, which includes a toroidal magnet and six planes of tracking detectors, coupled to a vertex spectrometer, equipped with Si MAPS immersed in a dipole field. High luminosity is an essential requirement for the experiment, with the goal of taking data with 10$^6$ incident ions/s, at collision energies ranging from $\sqrt{s_{\rm NN}} = 6.3$ GeV ($E_{\rm lab}= 20$ A GeV) to top SPS energy ($\sqrt{s_{\rm NN}} = 17.3$ GeV, $E_{\rm lab}= 158$ A GeV). This document presents the physics motivation, the foreseen experimental set-up including integration and radioprotection studies, the current detector choices together with the status of the corresponding R&D, and the outcome of physics performance studies. A preliminary cost evaluation is also carried out., Comment: Letter of Intent submitted to the CERN SPSC

Published

2022

4. Design of beam optics and radiation protection concept for the NA60+ heavy-ion experiment at CERN

Author

Gerbershagen, A., Ahdida, C., Bernhard, J., Clerc, V., Girod, S., Scomparin, E., Usai, G., and Vincke, H.

Subjects

Physics - Accelerator Physics

Abstract

NA60+ is a fixed target experiment proposed in the framework of the Physics Beyond Colliders programme at CERN. It aims to precisely measure the hard and electromagnetic probes in nuclear collisions. Initially proposed for the underground cavern ECN3 with very high beam intensities, the experiment now foresees a location in the EHN1 surface hall which was shown to have a limited impact on the physics performance in spite of a significant reduction of beam intensity and detector size. The potential installation and operation of the experiment with the ion beams from the Super Proton Synchrotron (SPS) has been examined regarding detector integration, beam physics, radiation protection and shielding requirements. The integration of the experiment is considered feasible, but would require a significant reconfiguration of the existing hall infrastructure with regards to shielding and layout., Comment: 21 pages, 15 figures, submitted to Nucl. Instr. Meth. A. Editor: A. Gerbershagen

Published

2022

5. Characterization of the PTW 34031 ionization chamber (PMI) at RCNP with high energy neutrons ranging from 100 – 392 MeV

Author

Theis C., Carbonez P., Feldbaumer E., Forkel-Wirth D., Jaegerhofer L., Pangallo M., Perrin D., Urscheler C., Roesler S., Vincke H., Widorski M., Iwamoto Y., Hagiwara M., Satoh D., Iwase H., Yashima H., Matsumoto T., Masuda A., Nishiyama J., Harano H., Itoga T., Nakamura T., Sato T., Nakane Y., Nakashima H., Sakamoto Y., Taniguchi S., Nakao N., Tamii A., Shima T., and Hatanaka K.

Subjects

Physics, QC1-999

Abstract

Radiation monitoring at high energy proton accelerators poses a considerable challenge due to the complexity of the encountered stray radiation fields. These environments comprise a wide variety of different particle types and span from fractions of electron-volts up to several terra electron-volts. As a consequence the use of Monte Carlo simulation programs like FLUKA is indispensable to obtain appropriate field-specific calibration factors. At many locations of the LHC a large contribution to the particle fluence is expected to originate from high-energy neutrons and thus, benchmark experiments with mono-energetic neutron beams are of high importance to verify the aforementioned detector response calculations. This paper summarizes the results of a series of benchmark experiments with quasi mono-energetic neutrons of 100, 140, 200, 250 and 392 MeV that have been carried out at RCNP - Osaka University, during several campaigns between 2006 and 2014.

Published

2017

6. A Shielding Concept for the MedAustron Facility

Author

Jägerhofer L., Feldbaumer E., Roesler S., Theis C., and Vincke H.

Subjects

EBG MedAustron GmbH, Shielding Calculations, Hadron Therapy, FLUKA, Physics, QC1-999

Abstract

MedAustron is a synchrotron based accelerator facility for cancer therapy and research in Wiener Neustadt, 50 km south of Vienna. The facility will provide protons up to kinetic energies of 250 MeV and carbon ions up to 400 MeV/n for ion beam therapy. Additionally, protons up to 800 MeV kinetic energy will be used in a dedicated room for non-clinical research. In order to obtain a shielding concept for this facility a detailed geometry of the accelerator facility was implemented into the Monte-Carlo code FLUKA and shielding simulations were performed. In the course of these simulations the contributions of different particle types to the mixed fields around the accelerator and behind shielding were analysed. In an iterative process with the architect the final design of the shielding concept was developed until it was capable of reducing the effect of secondary radiation on humans and the environment below Austrian legal limits.

Published

2017

7. Analysis of Proton Bunch Parameters in the AWAKE Experiment

Author

Hafych, V., Caldwell, A., Agnello, R., Ahdida, C. C., Aladi, M., Goncalves, M. C. Amoedo, Andrebe, Y., Apsimon, O., Apsimon, R., Bachmann, A. -M., Baistrukov, M. A., Batsch, F., Bergamaschi, M., Blanchard, P., Burrows, P. N., Buttenschön, B., Chappell, J., Chevallay, E., Chung, M., Cooke, D. A., Damerau, H., Davut, C., Demeter, G., Dexter, A., Doebert, S., Farmer, J., Fasoli, A., Fedosseev, V. N., Fiorito, R., Fonseca, R. A., Furno, I., Gessner, S., Gorn, A. A., Granados, E., Granetzny, M., Graubner, T., Grulke, O., Gschwendtner, E., Guran, E. D., Henderson, J. R., Hüther, M., Kedves, M. Á., Khudyakov, V., Kim, S. -Y., Kraus, F., Krupa, M., Lefevre, T., Liang, L., Lopes, N., Lotov, K. V., Mazzoni, S., Godoy, D. Medina, Moody, J. T., Moon, K., Guzmán, P. I. Morales, Moreira, M., Nechaeva, T., Nowak, E., Pakuza, C., Panuganti, H., Pardons, A., Perera, A., Pucek, J., Pukhov, A., Ráczkevi, B., Ramjiawan, R. L., Rey, S., Schmitz, O., Senes, E., Silva, L. O., Stollberg, C., Sublet, A., Topaloudis, A., Torrado, N., Tuev, P. V., Turner, M., Velotti, F., Verra, L., Vieira, J., Vincke, H., Welsch, C. P., Wendt, M., Wing, M., Wolfenden, J., Woolley, B., Xia, G., Zepp, M., and Della Porta, G. Zevi

Subjects

Physics - Accelerator Physics, High Energy Physics - Experiment

Abstract

A precise characterization of the incoming proton bunch parameters is required to accurately simulate the self-modulation process in the Advanced Wakefield Experiment (AWAKE). This paper presents an analysis of the parameters of the incoming proton bunches used in the later stages of the AWAKE Run 1 data-taking period. The transverse structure of the bunch is observed at multiple positions along the beamline using scintillating or optical transition radiation screens. The parameters of a model that describes the bunch transverse dimensions and divergence are fitted to represent the observed data using Bayesian inference. The analysis is tested on simulated data and then applied to the experimental data.

Published

2021

8. Scandium thermal release from activated [formula omitted]Ti and [formula omitted]V target materials in mixed particle fields: Investigation of parameters relevant for isotope mass separation

Author

Mamis, E., Kalnina, P., Duchemin, C., Lambert, L., Conan, N., Deschamps, M., Dorsival, A., Froeschl, R., Ruiz, F. Ogallar, Theis, C., Vincke, H., Crepieux, B., Rothe, S., Pajuste, E., and Stora, T.

Published

2024

9. Simulation and Experimental Study of Proton Bunch Self-Modulation in Plasma with Linear Density Gradients

Author

Guzmán, P. I. Morales, Muggli, P., Agnello, R., Ahdida, C. C., Aladi, M., Goncalves, M. C. Amoedo, Andrebe, Y., Apsimon, O., Apsimon, R., Bachmann, A. -M., Baistrukov, M. A., Batsch, F., Bergamaschi, M., Blanchard, P., Braunmüller, F., Burrows, P. N., Buttenschön, B., Caldwell, A., Chappell, J., Chevallay, E., Chung, M., Cooke, D. A., Damerau, H., Davut, C., Demeter, G., Dexter, A., Doebert, S., Farmer, J., Fasoli, A., Fedosseev, V. N., Fiorito, R., Fonseca, R. A., Furno, I., Gessner, S., Gorn, A. A., Granados, E., Granetzny, M., Graubner, T., Grulke, O., Gschwendtner, E., Guran, E. D., Hafych, V., Henderson, J. R., Hüther, M., Kedves, M. Á., Khudyakov, V., Kim, S. -Y., Kraus, F., Krupa, M., Lefevre, T., Liang, L., Lopes, N., Lotov, K. V., Martyanov, M., Mazzoni, S., Godoy, D. Medina, Moody, J. T., Moon, K., Moreira, M., Nechaeva, T., Nowak, E., Pakuza, C., Panuganti, H., Pardons, A., Perera, A., Pucek, J., Pukhov, A., Ráczkevi, B., Ramjiawan, R. L., Rey, S., Schmitz, O., Senes, E., Silva, L. O., Stollberg, C., Sublet, A., Topaloudis, A., Torrado, N., Tuev, P. V., Turner, M., Velotti, F., Verra, L., Vieira, J., Vincke, H., Welsch, C. P., Wendt, M., Wing, M., Wolfenden, J., Woolley, B., Xia, G., Zepp, M., and Della Porta, G. Zevi

Subjects

Physics - Plasma Physics, Physics - Accelerator Physics

Abstract

We present numerical simulations and experimental results of the self-modulation of a long proton bunch in a plasma with linear density gradients along the beam path. Simulation results agree with the experimental results reported in arXiv:2007.14894v2: with negative gradients, the charge of the modulated bunch is lower than with positive gradients. In addition, the bunch modulation frequency varies with gradient. Simulation results show that dephasing of the wakefields with respect to the relativistic protons along the plasma is the main cause for the loss of charge. The study of the modulation frequency reveals details about the evolution of the self-modulation process along the plasma. In particular for negative gradients, the modulation frequency across time-resolved images of the bunch indicates the position along the plasma where protons leave the wakefields. Simulations and experimental results are in excellent agreement., Comment: 13 pages, 11 figures

Published

2021

10. Transition between Instability and Seeded Self-Modulation of a Relativistic Particle Bunch in Plasma

Author

Batsch, F., Muggli, P., Agnello, R., Ahdida, C. C., Goncalves, M. C. Amoedo, Andrebe, Y., Apsimon, O., Apsimon, R., Bachmann, A. -M., Baistrukov, M. A., Blanchard, P., Braunmüller, F., Burrows, P. N., Buttenschön, B., Caldwell, A., Chappell, J., Chevallay, E., Chung, M., Cooke, D. A., Damerau, H., Davut, C., Demeter, G., Deubner, H. L., Doebert, S., Farmer, J., Fasoli, A., Fedosseev, V. N., Fiorito, R., Fonseca, R. A., Friebel, F., Furno, I., Garolfi, L., Gessner, S., Gorgisyan, I., Gorn, A. A., Granados, E., Granetzny, M., Graubner, T., Grulke, O., Gschwendtner, E., Hafych, V., Helm, A., Henderson, J. R., Hüther, M., Kargapolov, I. Yu., Kim, S. -Y., Kraus, F., Krupa, M., Lefevre, T., Liang, L., Liu, S., Lopes, N., Lotov, K. V., Martyanov, M., Mazzoni, S., Godoy, D. Medina, Minakov, V. A., Moody, J. T., Moon, K., Guzmán, P. I. Morales, Moreira, M., Nechaeva, T., Nowak, E., Pakuza, C., Panuganti, H., Pardons, A., Perera, A., Pucek, J., Pukhov, A., Ramjiawan, R. L., Rey, S., Rieger, K., Schmitz, O., Senes, E., Silva, L. O., Speroni, R., Spitsyn, R. I., Stollberg, C., Sublet, A., Topaloudis, A., Torrado, N., Tuev, P. V., Turner, M., Velotti, F., Verra, L., Verzilov, V. A., Vieira, J., Vincke, H., Welsch, C. P., Wendt, M., Wing, M., Wiwattananon, P., Wolfenden, J., Woolley, B., Xia, G., Zepp, M., and Della Porta, G. Zevi

Subjects

Physics - Plasma Physics, Physics - Accelerator Physics

Abstract

We use a relativistic ionization front to provide various initial transverse wakefield amplitudes for the self-modulation of a long proton bunch in plasma. We show experimentally that, with sufficient initial amplitude ($\ge(4.1\pm0.4)$ MV/m), the phase of the modulation along the bunch is reproducible from event to event, with 3 to 7% (of 2$\pi$) rms variations all along the bunch. The phase is not reproducible for lower initial amplitudes. We observe the transition between these two regimes. Phase reproducibility is essential for deterministic external injection of particles to be accelerated., Comment: Letter and Supplemental Material, 6 figures, 8 pages

Published

2020

11. A combined approach for the calculation of activation yields and the characterization of materials for a medical cyclotron

Author

Bonvin, V., Bochud, F., Theis, C., Vincke, H., Damet, J., and Geyer, R.

Published

2024

12. Scandium thermal release from activated natTi and natV target materials in mixed particle fields: Investigation of parameters relevant for isotope mass separation

Author

Mamis, E., primary, Kalnina, P., additional, Duchemin, C., additional, Lambert, L., additional, Conan, N., additional, Deschamps, M., additional, Dorsival, A., additional, Froeschl, R., additional, Ruiz, F. Ogallar, additional, Theis, C., additional, Vincke, H., additional, Crepieux, B., additional, Rothe, S., additional, Pajuste, E., additional, and Stora, T., additional

Published

2024

13. Experimental observation of proton bunch modulation in a plasma, at varying plasma densities

Author

Adli, E., Ahuja, A., Apsimon, O., Apsimon, R., Bachmann, A. -M., Barrientos, D., Barros, M. M., Batkiewicz, J., Batsch, F., Bauche, J., Olsen, V. K. Berglyd, Bernardini, M., Biskup, B., Boccardi, A., Bogey, T., Bohl, T., Bracco, C., Braunmüller, F., Burger, S., Burt, G., Bustamante, S., Buttenschön, B., Caldwell, A., Cascella, M., Chappell, J., Chevallay, E., Chung, M., Cooke, D., Damerau, H., Deacon, L., Deubner, L. H., Dexter, A., Doebert, S., Farmer, J., Fedosseev, V. N., Fior, G., Fiorito, R., Fonseca, R. A., Friebel, F., Garolfi, L., Gessner, S., Gorgisyan, I., Gorn, A. A., Granados, E., Grulke, O., Gschwendtner, E., Guerrero, A., Hansen, J., Helm, A., Henderson, J. R., Hessler, C., Hoe, W., Hüther, M., Ibison, M., Jensen, L., Jolly, S., Keeble, F., Kim, S. -Y., Kraus, F., Lefevre, T., LeGodec, G., Li, Y., Liu, S., Lopes, N., Lotov, K. V., Brun, L. Maricalva, Martyanov, M., Mazzoni, S., Godoy, D. Medina, Minakov, V. A., Mitchell, J., Molendijk, J. C., Mompo, R., Moody, J. T., Moreira, M., Muggli, P., Mutin, C., Öz, E., Ozturk, E., Pasquino, C., Pardons, A., Asmus, F. Pena, Pepitone, K., Perera, A., Petrenko, A., Pitman, S., Plyushchev, G., Pukhov, A., Rey, S., Rieger, K., Ruhl, H., Schmidt, J. S., Shalimova, I. A., Shaposhnikova, E., Sherwood, P., Silva, L. O., Soby, L., Sosedkin, A. P., Speroni, R., Spitsyn, R. I., Tuev, P. V., Turner, M., Velotti, F., Verra, L., Verzilov, V. A., Vieira, J., Vincke, H., Welsch, C. P., Williamson, B., Wing, M., Woolley, B., and Xia, G.

Subjects

Physics - Accelerator Physics, Physics - Plasma Physics

Abstract

We give direct experimental evidence for the observation of the full transverse self-modulation of a relativistic proton bunch propagating through a dense plasma. The bunch exits the plasma with a density modulation resulting from radial wakefield effects with a period reciprocal to the plasma frequency. We show that the modulation is seeded by using an intense laser pulse co-propagating with the proton bunch which creates a relativistic ionization front within the bunch. We show by varying the plasma density over one order of magnitude that the modulation period scales with the expected dependence on the plasma density., Comment: 4 figures, AWAKE collaboration paper, Submitted to PRL

Published

2018

14. Design Development for the Beam Dump Facility Target Complex at CERN

Author

Kershaw, K., Grenard, J. -L., Calviani, M., Ahdida, C., Casolino, M., Delavalle, S., Hounsome, D., Jacobsson, R., Lamont, M., Sola, E. Lopez, Scott, R., Vlachoudis, V., and Vincke, H.

Subjects

Physics - Instrumentation and Detectors, Physics - Accelerator Physics

Abstract

CERN has launched a study phase to evaluate the feasibility of a new high-intensity beam dump facility at the CERN Super Proton Synchrotron accelerator with the primary goal of exploring Hidden Sector models and searching for Light Dark Matter, but which also offers opportunities for other fixed target flavour physics programs such as rare tau lepton decays and tau neutrino studies. The new facility will require - among other infrastructure - a target complex in which a dense target/dump will be installed, capable of absorbing the entire energy of the beam extracted from the SPS accelerator. In theory, the target/dump could produce very weakly interacting particles, to be investigated by a suite of particle detectors to be located downstream of the target complex. As part of the study, a development design of the target complex has been produced, taking into account the handling and remote handling operations needed through the lifetime of the facility. Two different handling concepts have been studied and both resulting designs are presented., Comment: 26 pages, 30 figures

Published

2018

15. A desorption model for the code SOLIDUSS and its experimental benchmarking

Author

Ogallar Ruiz, F., Vincke, H., Porras, I., and Theis, C.

Published

2022

16. AWAKE readiness for the study of the seeded self-modulation of a 400\,GeV proton bunch

Author

Muggli, P., Adli, E., Apsimon, R., Asmus, F., Baartman, R., Bachmann, A. -M., Marin, M. Barros, Batsch, F., Bauche, J., Olsen, V. K. Berglyd, Bernardini, M., Biskup, B., Boccardi, A., Bogey, T., Bohl, T., Bracco, C., Braunmuller, F., Burger, S., Burt, G., Bustamante, S., Buttenschon, B., Butterworth, A., Caldwell, A., Cascella, M., Chevallay, E., Chung, M., Damerau, H., Deacon, L., Dexter, A., Dirksen, P., Doebert, S., Farmer, J., Fedosseev, V., Feniet, T., Fior, G., Fiorito, R., Fonseca, R., Friebel, F., Gander, P., Gessner, S., Gorgisyan, I., Gorn, A. A., Grulke, O., Gschwendtner, E., Guerrero, A., Hansen, J., Hessler, C., Hofle, W., Holloway, J., Huther, M., Ibison, M., Islam, M. R., Jensen, L., Jolly, S., Kasim, M., Keeble, F., Kim, S. -Y., Krause, F., Lasheen, A., Lefevre, T., LeGodec, G., Li, Y., Liu, S., Lopes, N., Lotov, K. V., Martyanov, M., Mazzoni, S., Godoy, D. Medina, Mete, O., Minakov, V. A., Mompo, R., Moody, J., Moreira, M. T., Mitchell, J., Mutin, C., Norreys, P., Oz, E., Ozturk, E., Pauw, W., Pardone, A., Pasquino, C., Pepitone, K., Petrenko, A., Pitmann, S., Plyushchev, G., Pukhov, A., Rieger, K., Ruhl, H., Schmidt, J., Shalimova, I. A., Shaposhnikova, E., Sherwood, P., Silva, L., Sosedkin, A. P., Spitsyn, R. I., Szczurek, K., Thomas, J., Tuev, P. V., Turner, M., Verzilov, V., Vieira, J., Vincke, H., Welsch, C. P., Williamson, B., Wing, M., Xia, G., and Zhang, H.

Subjects

Physics - Plasma Physics, Physics - Accelerator Physics

Abstract

AWAKE is a proton-driven plasma wakefield acceleration experiment. % We show that the experimental setup briefly described here is ready for systematic study of the seeded self-modulation of the 400\,GeV proton bunch in the 10\,m-long rubidium plasma with density adjustable from 1 to 10$\times10^{14}$\,cm$^{-3}$. % We show that the short laser pulse used for ionization of the rubidium vapor propagates all the way along the column, suggesting full ionization of the vapor. % We show that ionization occurs along the proton bunch, at the laser time and that the plasma that follows affects the proton bunch. %, Comment: Presented as an invited talk at the EPS=Plasma Physics Conference 2017

Published

2017

17. Design and early operation of a new-generation internal beam dump for CERN’s Super Proton Synchrotron

Author

Francia, A. Romero, primary, Marcone, A. Perillo, additional, Pianese, S., additional, Andersen, K., additional, Izquierdo, G. Arnau, additional, Briz, J. A., additional, Perez, D. Carbajo, additional, Carlier, E., additional, Coiffet, T., additional, Esposito, L. S., additional, Grenard, J. L., additional, Grenier, D., additional, Humbert, J., additional, Kershaw, K., additional, Lendaro, J., additional, Rolo, A. Ortega, additional, Scibor, K., additional, Senajova, D., additional, Sgobba, S., additional, Sharp, C., additional, Steyaert, D., additional, Velotti, F. M., additional, Vincke, H., additional, Vlachoudis, V., additional, and Calviani, M., additional

Published

2024

18. AWAKE, The Advanced Proton Driven Plasma Wakefield Acceleration Experiment at CERN

Author

Gschwendtner, E., Adli, E., Amorim, L., Apsimon, R., Assmann, R., Bachmann, A. -M., Batsch, F., Bauche, J., Olsen, V. K. Berglyd, Bernardini, M., Bingham, R., Biskup, B., Bohl, T., Bracco, C., Burrows, P. N., Burt, G., Buttenschon, B., Butterworth, A., Caldwell, A., Cascella, M., Chevallay, E., Cipiccia, S., Damerau, H., Deacon, L., Dirksen, P., Doebert, S., Dorda, U., Farmer, J., Fedosseev, V., Feldbaumer, E., Fiorito, R., Fonseca, R., Friebel, F., Gorn, A. A., Grulke, O., Hansen, J., Hessler, C., Hofle, W., Holloway, J., Huther, M., Jaroszynski, D., Jensen, L., Jolly, S., Joulaei, A., Kasim, M., Keeble, F., Li, Y., Liu, S., Lopes, N., Lotov, K. V., Mandry, S., Martorelli, R., Martyanov, M., Mazzoni, S., Mete, O., Minakov, V. A., Mitchell, J., Moody, J., Muggli, P., Najmudin, Z., Norreys, P., Oz, E., Pardons, A., Pepitone, K., Petrenko, A., Plyushchev, G., Pukhov, A., Rieger, K., Ruhl, H., Salveter, F., Savard, N., Schmidt, J., Seryi, A., Shaposhnikova, E., Sheng, Z. M., Sherwood, P., Silva, L., Soby, L., Sosedkin, A. P., Spitsyn, R. I., Trines, R., Tuev, P. V., Turner, M., Verzilov, V., Vieira, J., Vincke, H., Wei, Y., Welsch, C. P., Wing, M., Xia, G., and Zhang, H.

Subjects

Physics - Accelerator Physics, Physics - Plasma Physics

Abstract

The Advanced Proton Driven Plasma Wakefield Acceleration Experiment (AWAKE) aims at studying plasma wakefield generation and electron acceleration driven by proton bunches. It is a proof-of-principle R&D experiment at CERN and the world's first proton driven plasma wakefield acceleration experiment. The AWAKE experiment will be installed in the former CNGS facility and uses the 400 GeV/c proton beam bunches from the SPS. The first experiments will focus on the self-modulation instability of the long (rms ~12 cm) proton bunch in the plasma. These experiments are planned for the end of 2016. Later, in 2017/2018, low energy (~15 MeV) electrons will be externally injected to sample the wakefields and be accelerated beyond 1 GeV. The main goals of the experiment will be summarized. A summary of the AWAKE design and construction status will be presented., Comment: 7 pages, 7 figures, 2 tables

Published

2015

19. Path to AWAKE: Evolution of the concept

Author

Caldwell, A., Adli, E., Amorim, L., Apsimon, R., Argyropoulos, T., Assmann, R., Bachmann, A. -M., Batsch, F., Bauche, J., Olsen, V. K. Berglyd, Bernardini, M., Bingham, R., Biskup, B., Bohl, T., Bracco, C., Burrows, P. N., Burt, G., Buttenschon, B., Butterworth, A., Cascella, M., Chattopadhyay, S., Chevallay, E., Cipiccia, S., Damerau, H., Deacon, L., Dirksen, P., Doebert, S., Dorda, U., Elsen, E., Farmer, J., Fartoukh, S., Fedosseev, V., Feldbaumer, E., Fiorito, R., Fonseca, R., Friebel, F., Geschonke, G., Goddard, B., Gorn, A. A., Grulke, O., Gschwendtner, E., Hansen, J., Hessler, C., Hillenbrand, S., Hofle, W., Holloway, J., Huang, C., Huther, M., Jaroszynski, D., Jensen, L., Jolly, S., Joulaei, A., Kasim, M., Keeble, F., Kersevan, R., Kumar, N., Li, Y., Liu, S., Lopes, N., Lotov, K. V., Lu, W., Machacek, J., Mandry, S., Martin, I., Martorelli, R., Martyanov, M., Mazzoni, S., Meddahi, M., Merminga, L., Mete, O., Minakov, V. A., Mitchell, J., Moody, J., Muller, A. -S., Najmudin, Z., Noakes, T. C. Q., Norreys, P., Osterhoff, J., Oz, E., Pardons, A., Pepitone, K., Petrenko, A., Plyushchev, G., Pozimski, J., Pukhov, A., Reimann, O., Rieger, K., Roesler, S., Ruhl, H., Rusnak, T., Salveter, F., Savard, N., Schmidt, J., von der Schmitt, H., Seryi, A., Shaposhnikova, E., Sheng, Z. M., Sherwood, P., Silva, L., Simon, F., Soby, L., Sosedkin, A. P., Spitsyn, R. I., Tajima, T., Tarkeshian, R., Timko, H., Trines, R., Tueckmantel, T., Tuev, P. V., Turner, M., Velotti, F., Verzilov, V., Vieira, J., Vincke, H., Wei, Y., Welsch, C. P., Wing, M., Xia, G., Yakimenko, V., Zhang, H., and Zimmermann, F.

Subjects

Physics - Plasma Physics, Physics - Accelerator Physics

Abstract

This report describes the conceptual steps in reaching the design of the AWAKE experiment currently under construction at CERN. We start with an introduction to plasma wakefield acceleration and the motivation for using proton drivers. We then describe the self-modulation instability --- a key to an early realization of the concept. This is then followed by the historical development of the experimental design, where the critical issues that arose and their solutions are described. We conclude with the design of the experiment as it is being realized at CERN and some words on the future outlook. A summary of the AWAKE design and construction status as presented in this conference is given in [1]., Comment: 15 pages, 24 figures, 1 table, 111 references, 121 author from 36 organizations

Published

2015

20. Indirect Self-Modulation Instability Measurement Concept for the AWAKE Proton Beam

Author

Turner, M., Petrenko, A., Biskup, B., Burger, S., Gschwendtner, E., Lotov, K. V., Mazzoni, S., and Vincke, H.

Subjects

Physics - Plasma Physics

Abstract

AWAKE, the Advanced Proton-Driven Plasma Wakefield Acceleration Experiment, is a proof-of-principle R&D experiment at CERN using a 400 GeV/c proton beam from the CERN SPS (longitudinal beam size sigma_z = 12 cm) which will be sent into a 10 m long plasma section with a nominal density of approx. 7x10^14 atoms/cm3 (plasma wavelength lambda_p = 1.2mm). In this paper we show that by measuring the time integrated transverse profile of the proton bunch at two locations downstream of the AWAKE plasma, information about the occurrence of the self-modulation instability (SMI) can be inferred. In particular we show that measuring defocused protons with an angle of 1 mrad corresponds to having electric fields in the order of GV/m and fully developed self-modulation of the proton bunch. Additionally, by measuring the defocused beam edge of the self-modulated bunch, information about the growth rate of the instability can be extracted. If hosing instability occurs, it could be detected by measuring a non-uniform defocused beam shape with changing radius. Using a 1 mm thick Chromox scintillation screen for imaging of the self-modulated proton bunch, an edge resolution of 0.6 mm and hence a SMI saturation point resolution of 1.2 m can be achieved., Comment: 4 pages, 4 figures, EAAC conference proceedings

Published

2015

21. The LBNO long-baseline oscillation sensitivities with two conventional neutrino beams at different baselines

Author

Collaboration, LAGUNA-LBNO, Agarwalla, S. K., Agostino, L., Aittola, M., Alekou, A., Andrieu, B., Antoniou, F., Asfandiyarov, R., Autiero, D., Bésida, O., Balik, A., Ballett, P., Bandac, I., Banerjee, D., Bartmann, W., Bay, F., Biskup, B., Blebea-Apostu, A. M., Blondel, A., Bogomilov, M., Bolognesi, S., Borriello, E., Brancus, I., Bravar, A., Buizza-Avanzini, M., Caiulo, D., Calin, M., Calviani, M., Campanelli, M., Cantini, C., Cata-Danil, G., Chakraborty, S., Charitonidis, N., Chaussard, L., Chesneanu, D., Chipesiu, F., Crivelli, P., Dawson, J., De Bonis, I., Declais, Y., Sanchez, P. Del Amo, Delbart, A., Di Luise, S., Duchesneau, D., Dumarchez, J., Efthymiopoulos, I., Eliseev, A., Emery, S., Enqvist, T., Enqvist, K., Epprecht, L., Erykalov, A. N., Esanu, T., Franco, D., Friend, M., Galymov, V., Gavrilov, G., Gendotti, A., Giganti, C., Gilardoni, S., Goddard, B., Gomoiu, C. M., Gornushkin, Y. A., Gorodetzky, P., Haesler, A., Hasegawa, T., Horikawa, S., Huitu, K., Izmaylov, A., Jipa, A., Kainulainen, K., Karadzhov, Y., Khabibullin, M., Khotjantsev, A., Kopylov, A. N., Korzenev, A., Kosyanenko, S., Kryn, D., Kudenko, Y., Kuusiniemi, P., Lazanu, I., Lazaridis, C., Levy, J. -M., Loo, K., Maalampi, J., Margineanu, R. M., Marteau, J., Martin-Mari, C., Matveev, V., Mazzucato, E., Mefodiev, A., Mineev, O., Mirizzi, A., Mitrica, B., Murphy, S., Nakadaira, T., Narita, S., Nesterenko, D. A., Nguyen, K., Nikolics, K., Noah, E., Novikov, Yu., Oprima, A., Osborne, J., Ovsyannikova, T., Papaphilippou, Y., Pascoli, S., Patzak, T., Pectu, M., Pennacchio, E., Periale, L., Pessard, H., Popov, B., Ravonel, M., Rayner, M., Resnati, F., Ristea, O., Robert, A., Rubbia, A., Rummukainen, K., Saftoiu, A., Sakashita, K., Sanchez-Galan, F., Sarkamo, J., Saviano, N., Scantamburlo, E., Sergiampietri, F., Sgalaberna, D., Shaposhnikova, E., Slupecki, M., Smargianaki, D., Stanca, D., Steerenberg, R., Sterian, A. R., Sterian, P., Stoica, S., Strabel, C., Suhonen, J., Suvorov, V., Toma, G., Tonazzo, A., Trzaska, W. H., Tsenov, R., Tuominen, K., Valram, M., Vankova-Kirilova, G., Vannucci, F., Vasseur, G., Velotti, F., Velten, P., Venturi, V., Viant, T., Vihonen, S., Vincke, H., Vorobyev, A., Weber, A., Wu, S., Yershov, N., Zambelli, L., and Zito, M.

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Experiment

Abstract

The proposed Long Baseline Neutrino Observatory (LBNO) initially consists of $\sim 20$ kton liquid double phase TPC complemented by a magnetised iron calorimeter, to be installed at the Pyh\"asalmi mine, at a distance of 2300 km from CERN. The conventional neutrino beam is produced by 400 GeV protons accelerated at the SPS accelerator delivering 700 kW of power. The long baseline provides a unique opportunity to study neutrino flavour oscillations over their 1st and 2nd oscillation maxima exploring the $L/E$ behaviour, and distinguishing effects arising from $\delta_{CP}$ and matter. In this paper we show how this comprehensive physics case can be further enhanced and complemented if a neutrino beam produced at the Protvino IHEP accelerator complex, at a distance of 1160 km, and with modest power of 450 kW is aimed towards the same far detectors. We show that the coupling of two independent sub-MW conventional neutrino and antineutrino beams at different baselines from CERN and Protvino will allow to measure CP violation in the leptonic sector at a confidence level of at least $3\sigma$ for 50\% of the true values of $\delta_{CP}$ with a 20 kton detector. With a far detector of 70 kton, the combination allows a $3\sigma$ sensitivity for 75\% of the true values of $\delta_{CP}$ after 10 years of running. Running two independent neutrino beams, each at a power below 1 MW, is more within today's state of the art than the long-term operation of a new single high-energy multi-MW facility, which has several technical challenges and will likely require a learning curve., Comment: 21 pages, 12 figures

Published

2014

22. Optimised sensitivity to leptonic CP violation from spectral information: the LBNO case at 2300 km baseline

Author

Collaboration, LAGUNA-LBNO, Agarwalla, S. K., Agostino, L., Aittola, M., Alekou, A., Andrieu, B., Antoniou, F., Asfandiyarov, R., Autiero, D., Bésida, O., Balik, A., Ballett, P., Bandac, I., Banerjee, D., Bartmann, W., Bay, F., Biskup, B., Blebea-Apostu, A. M., Blondel, A., Bogomilov, M., Bolognesi, S., Borriello, E., Brancus, I., Bravar, A., Buizza-Avanzini, M., Caiulo, D., Calin, M., Calviani, M., Campanelli, M., Cantini, C., Cata-Danil, G., Chakraborty, S., Charitonidis, N., Chaussard, L., Chesneanu, D., Chipesiu, F., Crivelli, P., Dawson, J., De Bonis, I., Declais, Y., Sanchez, P. Del Amo, Delbart, A., Di~Luise, S., Duchesneau, D., Dumarchez, J., Efthymiopoulos, I., Eliseev, A., Emery, S., Enqvist, T., Enqvist, K., Epprecht, L., Erykalov, A. N., Esanu, T., Franco, D., Friend, M., Galymov, V., Gavrilov, G., Gendotti, A., Giganti, C., Gilardoni, S., Goddard, B., Gomoiu, C. M., Gornushkin, Y. A., Gorodetzky, P., Haesler, A., Hasegawa, T., Horikawa, S., Huitu, K., Izmaylov, A., Jipa, A., Kainulainen, K., Karadzhov, Y., Khabibullin, M., Khotjantsev, A., Kopylov, A. N., Korzenev, A., Kosyanenko, S., Kryn, D., Kudenko, Y., Kuusiniemi, P., Lazanu, I., Lazaridis, C., Levy, J. -M., Loo, K., Maalampi, J., Margineanu, R. M., Marteau, J., Martin-Mari, C., Matveev, V., Mazzucato, E., Mefodiev, A., Mineev, O., Mirizzi, A., Mitrica, B., Murphy, S., Nakadaira, T., Narita, S., Nesterenko, D. A., Nguyen, K., Nikolics, K., Noah, E., Novikov, Yu., Oprima, A., Osborne, J., Ovsyannikova, T., Papaphilippou, Y., Pascoli, S., Patzak, T., Pectu, M., Pennacchio, E., Periale, L., Pessard, H., Popov, B., Ravonel, M., Rayner, M., Resnati, F., Ristea, O., Robert, A., Rubbia, A., Rummukainen, K., Saftoiu, A., Sakashita, K., Sanchez-Galan, F., Sarkamo, J., Saviano, N., Scantamburlo, E., Sergiampietri, F., Sgalaberna, D., Shaposhnikova, E., Slupecki, M., Smargianaki, D., Stanca, D., Steerenberg, R., Sterian, A. R., Sterian, P., Stoica, S., Strabel, C., Suhonen, J., Suvorov, V., Toma, G., Tonazzo, A., Trzaska, W. H., Tsenov, R., Tuominen, K., Valram, M., Vankova-Kirilova, G., Vannucci, F., Vasseur, G., Velotti, F., Velten, P., Venturi, V., Viant, T., Vihonen, S., Vincke, H., Vorobyev, A., Weber, A., Wu, S., Yershov, N., Zambelli, L., and Zito, M.

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Experiment

Abstract

One of the main goals of the Long Baseline Neutrino Observatory (LBNO) is to study the $L/E$ behaviour (spectral information) of the electron neutrino and antineutrino appearance probabilities, in order to determine the unknown CP-violation phase $\delta_{CP}$ and discover CP-violation in the leptonic sector. The result is based on the measurement of the appearance probabilities in a broad range of energies, covering t he 1st and 2nd oscillation maxima, at a very long baseline of 2300 km. The sensitivity of the experiment can be maximised by optimising the energy spectra of the neutrino and anti-neutrino fluxes. Such an optimisation requires exploring an extended range of parameters describing in details the geometries and properties of the primary protons, hadron target and focusing elements in the neutrino beam line. In this paper we present a numerical solution that leads to an optimised energy spectra and study its impact on the sensitivity of LBNO to discover leptonic CP violation. In the optimised flux both 1st and 2nd oscillation maxima play an important role in the CP sensitivity. The studies also show that this configuration is less sensitive to systematic errors (e.g. on the total event rates) than an experiment which mainly relies on the neutrino-antineutrino asymmetry at the 1st maximum to determine the existence of CP-violation., Comment: 25 pages, 20 figures

Published

2014

23. Proton-driven plasma wakefield acceleration: a path to the future of high-energy particle physics

Author

AWAKE Collaboration, Assmann, R., Bingham, R., Bohl, T., Bracco, C., Buttenschon, B., Butterworth, A., Caldwell, A., Chattopadhyay, S., Cipiccia, S., Feldbaumer, E., Fonseca, R. A., Goddard, B., Gross, M., Grulke, O., Gschwendtner, E., Holloway, J., Huang, C., Jaroszynski, D., Jolly, S., Kempkes, P., Lopes, N., Lotov, K., Machacek, J., Mandry, S. R., McKenzie, J. W., Meddahi, M., Militsyn, B. L., Moschuering, N., Muggli, P., Najmudin, Z., Noakes, T. C. Q., Norreys, P. A., Oz, E., Pardons, A., Petrenko, A., Pukhov, A., Rieger, K., Reimann, O., Ruhl, H., Shaposhnikova, E., Silva, L. O., Sosedkin, A., Tarkeshian, R., Trines, R. M. G. N., Tuckmantel, T., Vieira, J., Vincke, H., Wing, M., and Xia, G.

Subjects

Physics - Accelerator Physics, High Energy Physics - Experiment, Physics - Plasma Physics

Abstract

New acceleration technology is mandatory for the future elucidation of fundamental particles and their interactions. A promising approach is to exploit the properties of plasmas. Past research has focused on creating large-amplitude plasma waves by injecting an intense laser pulse or an electron bunch into the plasma. However, the maximum energy gain of electrons accelerated in a single plasma stage is limited by the energy of the driver. Proton bunches are the most promising drivers of wakefields to accelerate electrons to the TeV energy scale in a single stage. An experimental program at CERN -- the AWAKE experiment -- has been launched to study in detail the important physical processes and to demonstrate the power of proton-driven plasma wakefield acceleration. Here we review the physical principles and some experimental considerations for a future proton-driven plasma wakefield accelerator., Comment: 12 pages, 5 figures, submitted to Plasma Phys. Control. Fusion special edition for LPAW 2013. Small updates after comments from Journal referees

Published

2014

24. The mass-hierarchy and CP-violation discovery reach of the LBNO long-baseline neutrino experiment

Author

Collaboration, LAGUNA-LBNO, Agarwalla, S. K., Agostino, L., Aittola, M., Alekou, A., Andrieu, B., Angus, D., Antoniou, F., Ariga, A., Ariga, T., Asfandiyarov, R., Autiero, D., Ballett, P., Bandac, I., Banerjee, D., Barker, G. J., Barr, G., Bartmann, W., Bay, F., Berardi, V., Bertram, I., Bésida, O., Blebea-Apostu, A. M., Blondel, A., Bogomilov, M., Borriello, E., Boyd, S., Brancus, I., Bravar, A., Buizza-Avanzini, M., Cafagna, F., Calin, M., Calviani, M., Campanelli, M., Cantini, C., Caretta, O., Cata-Danil, G., Catanesi, M. G., Cervera, A., Chakraborty, S., Chaussard, L., Chesneanu, D., Chipesiu, F., Christodoulou, G., Coleman, J., Crivelli, P., Davenne, T., Dawson, J., De Bonis, I., De Jong, J., Déclais, Y., Sanchez, P. Del Amo, Delbart, A., Densham, C., Di Lodovico, F., Di Luise, S., Duchesneau, D., Dumarchez, J., Efthymiopoulos, I., Eliseev, A., Emery, S., Enqvist, K., Enqvist, T., Epprecht, L., Ereditato, A., Erykalov, A. N., Esanu, T., Finch, A. J., Fitton, M. D., Franco, D., Galymov, V., Gavrilov, G., Gendotti, A., Giganti, C., Goddard, B., Gomez, J. J., Gomoiu, C. M., Gornushkin, Y. A., Gorodetzky, P., Grant, N., Haesler, A., Haigh, M. D., Hasegawa, T., Haug, S., Hierholzer, M., Hissa, J., Horikawa, S., Huitu, K., Ilic, J., Ioannisian, A. N., Izmaylov, A., Jipa, A., Kainulainen, K., Kalliokoski, T., Karadzhov, Y., Kawada, J., Khabibullin, M., Khotjantsev, A., Kokko, E., Kopylov, A. N., Kormos, L. L., Korzenev, A., Kosyanenko, S., Kreslo, I., Kryn, D., Kudenko, Y., Kudryavtsev, V. A., Kumpulainen, J., Kuusiniemi, P., Lagoda, J., Lazanu, I., Levy, J. -M., Litchfield, R. P., Loo, K., Loveridge, P., Maalampi, J., Magaletti, L., Margineanu, R. M., Marteau, J., Martin-Mari, C., Matveev, V., Mavrokoridis, K., Mazzucato, E., McCauley, N., Mercadante, A., Mineev, O., Mirizzi, A., Mitrica, B., Morgan, B., Murdoch, M., Murphy, S., Mursula, K., Narita, S., Nesterenko, D. A., Nguyen, K., Nikolics, K., Noah, E., Novikov, Yu., O'Keeffe, H., Odell, J., Oprima, A., Palladino, V., Papaphilippou, Y., Pascoli, S., Patzak, T., Payne, D., Pectu, M., Pennacchio, E., Periale, L., Pessard, H., Pistillo, C., Popov, B., Przewlocki, P., Quinto, M., Radicioni, E., Ramachers, Y., Ratoff, P. N., Ravonel, M., Rayner, M., Resnati, F., Ristea, O., Robert, A., Rondio, E., Rubbia, A., Rummukainen, K., Sacco, R., Saftoiu, A., Sakashita, K., Sarkamo, J., Sato, F., Saviano, N., Scantamburlo, E., Sergiampietri, F., Sgalaberna, D., Shaposhnikova, E., Slupecki, M., Sorel, M., Spooner, N. J. C., Stahl, A., Stanca, D., Steerenberg, R., Sterian, A. R., Sterian, P., Still, B., Stoica, S., Strauss, T., Suhonen, J., Suvorov, V., Szeptycka, M., Terri, R., Thompson, L. F., Toma, G., Tonazzo, A., Touramanis, C., Trzaska, W. H., Tsenov, R., Tuominen, K., Vacheret, A., Valram, M., Vankova-Kirilova, G., Vanucci, F., Vasseur, G., Velotti, F., Velten, P., Viant, T., Vincke, H., Virtanen, A., Vorobyev, A., Wark, D., Weber, A., Weber, M., Wiebusch, C., Wilson, J. R., Wu, S., Yershov, N., Zalipska, J., and Zito, M.

Subjects

High Energy Physics - Phenomenology

Abstract

The next generation neutrino observatory proposed by the LBNO collaboration will address fundamental questions in particle and astroparticle physics. The experiment consists of a far detector, in its first stage a 20 kt LAr double phase TPC and a magnetised iron calorimeter, situated at 2300 km from CERN and a near detector based on a high-pressure argon gas TPC. The long baseline provides a unique opportunity to study neutrino flavour oscillations over their 1st and 2nd oscillation maxima exploring the $L/E$ behaviour, and distinguishing effects arising from $\delta_{CP}$ and matter. In this paper we have reevaluated the physics potential of this setup for determining the mass hierarchy (MH) and discovering CP-violation (CPV), using a conventional neutrino beam from the CERN SPS with a power of 750 kW. We use conservative assumptions on the knowledge of oscillation parameter priors and systematic uncertainties. The impact of each systematic error and the precision of oscillation prior is shown. We demonstrate that the first stage of LBNO can determine unambiguously the MH to $>5\sigma$C.L. over the whole phase space. We show that the statistical treatment of the experiment is of very high importance, resulting in the conclusion that LBNO has $\sim$ 100% probability to determine the MH in at most 4-5 years of running. Since the knowledge of MH is indispensable to extract $\delta_{CP}$ from the data, the first LBNO phase can convincingly give evidence for CPV on the $3\sigma$C.L. using today's knowledge on oscillation parameters and realistic assumptions on the systematic uncertainties., Comment: 35 pages, 22 figures, added authors

Published

2013

25. Radiation protection issues after 20 years of LHC operation

Author

Forkel-Wirth, D., Magistris, M., Roesler, S., Theis, C., Ulrici, L., Vincke, H., and Vincke, Hz.

Subjects

Physics - Accelerator Physics

Abstract

Since November 2009, the LHC commissioning progresses very well, both with proton and lead beams. It will continue in 2011 and nominal LHC operation is expected to be attained in 2013. In parallel, plans for various LHC upgrades are under discussion, suggesting a High-Luminosity (HL) upgrade first and a High-Energy (HE) upgrade in a later state. Whereas the upgrade in luminosity would require the modification of only some few key accelerator components like the inner triplets, the upgrade in beam energy from 7 TeV to 16.5 TeV would require the exchange of all dipoles and of numerous other accelerator components. The paper gives an overview of the radiation protection issues related to the dismantling of LHC components prior to the installation of the HE-LHC components, i.e. after about 20 years of LHC operation. Two main topics will be discussed: (i) the exposure of workers to ionizing radiation during the dismantling of dipoles, inner triplets or collimators and experiments and (ii) the production, conditioning, interim storage and final disposal of radioactive waste., Comment: 3 pages, contribution to the EuCARD-AccNet-EuroLumi Workshop: The High-Energy Large Hadron Collider, Malta, 14 -- 16 Oct 2010; CERN Yellow Report CERN-2011-003, pp. 134-136

Published

2011

26. A combined approach for the calculation of activation yields and the characterisation of materials for a medical cyclotron

Author

Bonvin, V., primary, Bochud, F., additional, Theis, C., additional, Vincke, H., additional, Damet, J., additional, and Geyer, R., additional

Published

2023

27. The charged beam dumps for the international linear collider

Author

Appleby, R., Bennett, J. R. J., Broome, T., Densham, C., and Vincke, H.

Subjects

Physics - Accelerator Physics

Abstract

The baseline configuration of the International Linear Collider requires 2 beam dumps per interaction region, each rated to 18MW of beam power, together with additional beam dumps for tuning purposes and machine protection. The baseline design uses high pressure moving water dumps, first developed for the SLC and used in the TESLA design, although a gas based dump is also being considered. In this paper we discuss the progress made by the international community on both physics and engineering studies for the beam dumps., Comment: Presented at European Particle Accelerator Conference (EPAC 06), Edinburgh, Scotland, 26-30 Jun 2006

Published

2006

28. Comparison of air fluorescence and ionization measurements of E.M. shower depth profiles: test of a UHECR detector technique

Author

Belz, J., Cao, Z., Huentemeyer, P., Jui, C. C. H., Martens, K., Matthews, J., Maestas, M., Smith, J., Sokolsky, P., Springer, R. W., Thomas, J., Thomas, S., Chen, P., Field, C., Hast, C., Iverson, R., Ng, J. S. T., Odian, A., Reil, K., Vincke, H., Walz, D., Goldammer, A., Guest, D., Thomson, G., Chang, F-Y., Chen, C-C., Chen, C-W., Huang, M. A., Hwang, W-Y. P., and Lin, G-L.

Subjects

Astrophysics

Abstract

Measurements are reported on the fluorescence of air as a function of depth in electromagnetic showers initiated by bunches of 28.5 GeV electrons. The light yield is compared with the expected and observed depth profiles of ionization in the showers. It validates the use of atmospheric fluorescence profiles in measuring ultra high energy cosmic rays., Comment: 22 pages, 11 figures. Submitted to Astroparticle Physics

Published

2005

29. AWAKE, The Advanced Proton Driven Plasma Wakefield Acceleration Experiment at CERN

Author

Gschwendtner, E., Adli, E., Amorim, L., Apsimon, R., Assmann, R., Bachmann, A.-M., Batsch, F., Bauche, J., Berglyd Olsen, V.K., Bernardini, M., Bingham, R., Biskup, B., Bohl, T., Bracco, C., Burrows, P.N., Burt, G., Buttenschön, B., Butterworth, A., Caldwell, A., Cascella, M., Chevallay, E., Cipiccia, S., Damerau, H., Deacon, L., Dirksen, P., Doebert, S., Dorda, U., Farmer, J., Fedosseev, V., Feldbaumer, E., Fiorito, R., Fonseca, R., Friebel, F., Gorn, A.A., Grulke, O., Hansen, J., Hessler, C., Hofle, W., Holloway, J., Hüther, M., Jaroszynski, D., Jensen, L., Jolly, S., Joulaei, A., Kasim, M., Keeble, F., Li, Y., Liu, S., Lopes, N., Lotov, K.V., Mandry, S., Martorelli, R., Martyanov, M., Mazzoni, S., Mete, O., Minakov, V.A., Mitchell, J., Moody, J., Muggli, P., Najmudin, Z., Norreys, P., Öz, E., Pardons, A., Pepitone, K., Petrenko, A., Plyushchev, G., Pukhov, A., Rieger, K., Ruhl, H., Salveter, F., Savard, N., Schmidt, J., Seryi, A., Shaposhnikova, E., Sheng, Z.M., Sherwood, P., Silva, L., Soby, L., Sosedkin, A.P., Spitsyn, R.I., Trines, R., Tuev, P.V., Turner, M., Verzilov, V., Vieira, J., Vincke, H., Wei, Y., Welsch, C.P., Wing, M., Xia, G., and Zhang, H.

Published

2016

30. Indirect self-modulation instability measurement concept for the AWAKE proton beam

Author

Turner, M., Petrenko, A., Biskup, B., Burger, S., Gschwendtner, E., Lotov, K.V., Mazzoni, S., and Vincke, H.

Published

2016

31. Path to AWAKE: Evolution of the concept

Author

Caldwell, A., Adli, E., Amorim, L., Apsimon, R., Argyropoulos, T., Assmann, R., Bachmann, A.-M., Batsch, F., Bauche, J., Berglyd Olsen, V.K., Bernardini, M., Bingham, R., Biskup, B., Bohl, T., Bracco, C., Burrows, P.N., Burt, G., Buttenschön, B., Butterworth, A., Cascella, M., Chattopadhyay, S., Chevallay, E., Cipiccia, S., Damerau, H., Deacon, L., Dirksen, P., Doebert, S., Dorda, U., Elsen, E., Farmer, J., Fartoukh, S., Fedosseev, V., Feldbaumer, E., Fiorito, R., Fonseca, R., Friebel, F., Geschonke, G., Goddard, B., Gorn, A.A., Grulke, O., Gschwendtner, E., Hansen, J., Hessler, C., Hillenbrand, S., Hofle, W., Holloway, J., Huang, C., Hüther, M., Jaroszynski, D., Jensen, L., Jolly, S., Joulaei, A., Kasim, M., Keeble, F., Kersevan, R., Kumar, N., Li, Y., Liu, S., Lopes, N., Lotov, K.V., Lu, W., Machacek, J., Mandry, S., Martin, I., Martorelli, R., Martyanov, M., Mazzoni, S., Meddahi, M., Merminga, L., Mete, O., Minakov, V.A., Mitchell, J., Moody, J., Müller, A.-S., Najmudin, Z., Noakes, T.C.Q., Norreys, P., Osterhoff, J., Öz, E., Pardons, A., Pepitone, K., Petrenko, A., Plyushchev, G., Pozimski, J., Pukhov, A., Reimann, O., Rieger, K., Roesler, S., Ruhl, H., Rusnak, T., Salveter, F., Savard, N., Schmidt, J., von der Schmitt, H., Seryi, A., Shaposhnikova, E., Sheng, Z.M., Sherwood, P., Silva, L., Simon, F., Soby, L., Sosedkin, A.P., Spitsyn, R.I., Tajima, T., Tarkeshian, R., Timko, H., Trines, R., Tückmantel, T., Tuev, P.V., Turner, M., Velotti, F., Verzilov, V., Vieira, J., Vincke, H., Wei, Y., Welsch, C.P., Wing, M., Xia, G., Yakimenko, V., Zhang, H., and Zimmermann, F.

Published

2016

32. Monte Carlo simulations of the radiation environment for the CMS experiment

Author

Mallows, S., Azhgirey, I., Bayshev, I., Bergstrom, I., Cooijmans, T., Dabrowski, A., Glöggler, L., Guthoff, M., Kurochkin, I., Vincke, H., and Tajeda, S.

Published

2016

33. AWAKE: A Proton-Driven Plasma Wakefield Acceleration Experiment at CERN

Author

Bracco, C., Amorim, L.D., Assmann, R., Batsch, F., Bingham, R., Burt, G., Buttenschön, B., Butterworth, A., Caldwell, A., Chattopadhyay, S., Cipiccia, S., Deacon, L.C., Doebert, S., Dorda, U., Feldbaumer, E., Fonseca, R.A., Fedossev, V., Goddard, B., Grebenyuk, J., Grulke, O., Gschwendtner, E., Hansen, J., Hessler, C., Hofle, W., Holloway, J., Jaroszynski, D., Jenkins, M., Jensen, L., Jolly, S., Jones, R., Kasim, M.F., Lopes, N., Lotov, K., Mandry, S.R., Martyanov, M., Meddahi, M., Mete, O., Minakov, V., Moody, J., Muggli, P., Najmudin, Z., Norreys, P.A., Öz, E., Pardons, A., Petrenko, A., Pukhov, A., Rieger, K., Reimann, O., Seryi, A.A., Shaposhnikova, E., Sherwood, P., Silva, L.O., Sosedkin, A., Tarkeshian, R., Trines, R.M.G.M., Velotti, F.M., Vieira, J., Vincke, H., Welsch, C., Wing, M., and Xia, G.

Published

2016

34. Design of beam optics and radiation protection concept for NA60+ heavy-ion experiment at CERN

Author

Gerbershagen, A., primary, Ahdida, C., additional, Bernhard, J., additional, Clerc, V., additional, Girod, S., additional, Scomparin, E., additional, Usai, G., additional, and Vincke, H., additional

Published

2023

35. BDF/SHiP at the ECN3 high-intensity beam facility

Author

Aberle, O, Ahdida, C, Albanese, R, Alt, J, Alexandrov, A, Aoki, S, Aritunov, D, Arrutia, P, Bay, A, Balazs, K, Betancourt, C, Bezshyiko, I, Bezshyyko, O, Bick, D, Blanco, A, Bogomilov, M, Boiarska, I, Bondarenko, K, Bonivento, W M, Boyarsky, A, Bohles, M, Breton, D, Brignoli, A, Buonaura, A, Buontempo, S, Calviani, M, Campanelli, M, Centanni, D, Choi, K-Y, Climescu, M, Conaboy, A, Congedo, L, Cristinziani, M, Crupano, A, Dallavalle, G M, D'Ambrosio, N, de Asmundis, R, de Bryas, P, De Carvalho Saraiva, J, De Lellis, G, de Magistris, M, De Roeck, A, De Serio, M, De Simone, D, Dergachev, P, Deucher, P, Di Crescenzo, A, Dijkstra, H, Durhan, O, Dutheil, Y, Elikkaya, E, Esposito, L S, Fedotovs, F, Ferrillo, M, Ferro-Luzzi, M, Fini, R A, Fiorillo, G, Fischer, H, Fonte, P, Franqueira Ximenes, R, Fraser, M, Fresa, R, Fukuda, T, Galati, G, Galleazzi, F, Gilardoni, S, Golinka-Bezshyyko, L, Golovatiuk, A, Golutvin, A, Gorkavenko, V, Graverini, E, Grenard, J-L, Grewing, C, Griesemer, T, Guler, A M, Haefeli, G J, Hagner, C, Helo, J C, van Herwijnen, E, Hollnagel, A, Iuliano, A, Jacobsson, R, Jonker, M, Kadenko, I, Kain, V, Kamiscioglu, C, Kim, Y G, Kitagawa, N, Kodama, K, Kolev, D I, Komatsu, M, Kostyukhin, V, Krzempek, L, Kuleshov, S, Kurbatov, E, Lacker, H M, Lafarge, D, Lantwin, O, Lauria, A, Lee, K S, Lee, K Y, Leonardo, N, Loschiavo, V P, Lopes, L, Lyons, F, Maalmi, J, Magnan, A-M, Marsh, S, Marshall, A M, Martin Ruiz, J M, Mazzola, G, Mena Andrade, R F, Miano, A, Mikado, S, Mikulenko, A, Montesi, M C, Morishima, K, Muttoni, Y, Naganawa, N, Nakamura, M, Nakano, T, Navascues Cornago, A, Ninin, P, Ogawa, S, Osborne, J, Ovchynnikov, M, Owtscharenko, N, Park, B D, Pastore, A, Patel, M, Petridis, K, Prota, A, Quercia, A, Rademakers, A, Ramjiawan, R, Ratnikov, F, Redi, F, Reghunath, A, Rokujo, H, Ruchayskiy, O, Ruf, T, Sanchez Galan, F, Santos Dias, P, Sato, O, Schmidt-Parzefall, W, Schumann, M, Serra, N, Shaposhnikov, M, Shchutska, L, Shibuya, H, Simone, S, Soares, G, Sohn, J Y, Sokolenko, A, Soto, O, Takahashi, S, Tastet, J L, Timiryasov, I, Tioukov, V, Tommasini, D, Treille, D, Tsenov, R, Ulloa, P, Ursov, E, Vankova-Kirilova, G, Velotti, F, Vilchinski, S, Vincke, H, Visone, C, van Waasen, S, Vojtyla, P, Wertelaers, P, Wurm, M, Xella, S, Yilmaz, D, Yoon, C S, and Zamora Saa, J

Subjects

Detectors and Experimental Techniques

Abstract

The BDF/SHiP collaboration has proposed a general-purpose intensity-frontier experimental facility operating in beam-dump mode at the CERN SPS accelerator to search for feebly interacting GeV-scale particles and to perform measurements in neutrino physics. BDF/SHiP complements the world-wide program of New Physics searches by exploring a large region of parameter space which cannot be addressed by other experiments, and which reaches several orders of magnitude below existing bounds. The SHiP detector is sensitive both to decay and scattering signatures of models with heavy neutral leptons, dark photons, dark scalars, axion-like particles, light dark matter and other feebly interacting particles. In neutrino physics, BDF/SHiP can perform unprecedented measurements with tau neutrinos and neutrino-induced charm production. Following the Technical Proposal submitted in 2015, the subsequent three-year Comprehensive Design Study (CDS), and the recent study of BDF/SHiP in existing beam facilities around the SPS, this paper restates the motivation and reports on the implementation and physics performance of BDF/SHiP in the SPS ECN3 high-intensity beam facility.

Published

2022

36. Comparison of Bonner sphere responses calculated by different Monte Carlo codes at energies between 1 MeV and 1 GeV – Potential impact on neutron dosimetry at energies higher than 20 MeV

Author

Rühm, W., Mares, V., Pioch, C., Agosteo, S., Endo, A., Ferrarini, M., Rakhno, I., Rollet, S., Satoh, D., and Vincke, H.

Published

2014

37. Radiation Protection Considerations

Author

Adorisio, C., primary, Roesler, S., additional, Urscheler, C., additional, and Vincke, H., additional

Published

2015

38. Analysis of proton bunch parameters in the AWAKE experiment

Author

Hafych, V., additional, Caldwell, A., additional, Agnello, R., additional, Ahdida, C.C., additional, Aladi, M., additional, Amoedo Goncalves, M.C., additional, Andrebe, Y., additional, Apsimon, O., additional, Apsimon, R., additional, Bachmann, A.-M., additional, Baistrukov, M.A., additional, Batsch, F., additional, Bergamaschi, M., additional, Blanchard, P., additional, Burrows, P.N., additional, Buttenschön, B., additional, Chappell, J., additional, Chevallay, E., additional, Chung, M., additional, Cooke, D.A., additional, Damerau, H., additional, Davut, C., additional, Demeter, G., additional, Dexter, A., additional, Doebert, S., additional, Farmer, J., additional, Fasoli, A., additional, Fedosseev, V.N., additional, Fiorito, R., additional, Fonseca, R.A., additional, Furno, I., additional, Gessner, S., additional, Gorn, A.A., additional, Granados, E., additional, Granetzny, M., additional, Graubner, T., additional, Grulke, O., additional, Gschwendtner, E., additional, Guran, E.D., additional, Henderson, J.R., additional, Hüther, M., additional, Kedves, M.Á., additional, Khudyakov, V., additional, Kim, S.-Y., additional, Kraus, F., additional, Krupa, M., additional, Lefevre, T., additional, Liang, L., additional, Lopes, N., additional, Lotov, K.V., additional, Mazzoni, S., additional, Medina Godoy, D., additional, Moody, J.T., additional, Moon, K., additional, Morales Guzmán, P.I., additional, Moreira, M., additional, Nechaeva, T., additional, Nowak, E., additional, Pakuza, C., additional, Panuganti, H., additional, Pardons, A., additional, Perera, A., additional, Pucek, J., additional, Pukhov, A., additional, Ráczkevi, B., additional, Ramjiawan, R.L., additional, Rey, S., additional, Schmitz, O., additional, Senes, E., additional, Silva, L.O., additional, Stollberg, C., additional, Sublet, A., additional, Topaloudis, A., additional, Torrado, N., additional, Tuev, P.V., additional, Turner, M., additional, Velotti, F., additional, Verra, L., additional, Vieira, J., additional, Vincke, H., additional, Welsch, C.P., additional, Wendt, M., additional, Wing, M., additional, Wolfenden, J., additional, Woolley, B., additional, Xia, G., additional, Zepp, M., additional, and Zevi Della Porta, G., additional

Published

2021

39. SOLIDUSS: Solid-state diffusion software for radiation protection

Author

Ruiz, F. Ogallar, primary, Theis, C., additional, Porras, I., additional, and Vincke, H., additional

Published

2021

40. CNGS neutrino beam for long base-line experiments: present status and perspectives

Author

Autiero, D., Efthymiopoulos, I., Ferrari, A., Gschwendtner, E., Guglielmi, A., Lettry, J., Pardons, A., Pietropaolo, F., Rubbia, C., Sala, P.R., Sarchiapone, L., and Vincke, H.

Published

2009

41. The CNGS neutrino beam: status

Author

Autiero, D., Efthymiopoulos, I., Ferrari, A., Gschwendtner, E., Guglielmi, A., Lettry, J., Pardons, A., Pietropaolo, F., Sala, P.R., Sarchiapone, L., and Vincke, H.

Published

2009

42. Simulation of RPC performance for 511 keV photon detection

Author

Lippmann, C., Vincke, H., and Riegler, W.

Published

2009

43. Transition between Instability and Seeded Self-Modulation of a Relativistic Particle Bunch in Plasma

Author

Batsch, F, Muggli, P, Agnello, R, Ahdida, CC, Amoedo Goncalves, MC, Andrebe, Y, Apsimon, O, Apsimon, R, Bachmann, A-M, Baistrukov, MA, Blanchard, P, Braunmüller, F, Burrows, PN, Buttenschön, B, Caldwell, A, Chappell, J, Chevallay, E, Chung, M, Cooke, DA, Damerau, H, Davut, C, Demeter, G, Deubner, HL, Doebert, S, Farmer, J, Fasoli, A, Fedosseev, VN, Fiorito, R, Fonseca, RA, Friebel, F, Furno, I, Garolfi, L, Gessner, S, Gorgisyan, I, Gorn, AA, Granados, E, Granetzny, M, Graubner, T, Grulke, O, Gschwendtner, E, Hafych, V, Helm, A, Henderson, JR, Hüther, M, Kargapolov, I Yu, Kim, S-Y, Kraus, F, Krupa, M, Lefevre, T, Liang, L, Liu, S, Lopes, N, Lotov, KV, Martyanov, M, Mazzoni, S, Medina Godoy, D, Minakov, VA, Moody, JT, Moon, K, Morales Guzmán, PI, Moreira, M, Nechaeva, T, Nowak, E, Pakuza, C, Panuganti, H, Pardons, A, Perera, A, Pucek, J, Pukhov, A, Ramjiawan, RL, Rey, S, Rieger, K, Schmitz, O, Senes, E, Silva, LO, Speroni, R, Spitsyn, RI, Stollberg, C, Sublet, A, Topaloudis, A, Torrado, N, Tuev, PV, Turner, M, Velotti, F, Verra, L, Verzilov, VA, Vieira, J, Vincke, H, Welsch, CP, Wendt, M, Wing, M, Wiwattananon, P, Wolfenden, J, Woolley, B, Xia, G, Zepp, M, Zevi Della Porta, G, AWAKE Collaboration, and Collaboration, AWAKE

Subjects

Accelerator Physics (physics.acc-ph), Proton, Other Fields of Physics, Phase (waves), FOS: Physical sciences, General Physics and Astronomy, Ciências Naturais::Ciências Físicas [Domínio/Área Científica], 01 natural sciences, Instability, Relativistic particle, physics.plasm-ph, 0103 physical sciences, 010306 general physics, physics.acc-ph, Physics, acceleration, Plasma, electron-beam, Accelerators and Storage Rings, Physics - Plasma Physics, ddc, Plasma Physics (physics.plasm-ph), Transverse plane, Amplitude, Physics::Accelerator Physics, Physics - Accelerator Physics, Atomic physics, Event (particle physics)

Abstract

We use a relativistic ionization front to provide various initial transverse wakefield amplitudes for the self-modulation of a long proton bunch in plasma. We show experimentally that, with sufficient initial amplitude ($\ge(4.1\pm0.4)$ MV/m), the phase of the modulation along the bunch is reproducible from event to event, with 3 to 7% (of 2$\pi$) rms variations all along the bunch. The phase is not reproducible for lower initial amplitudes. We observe the transition between these two regimes. Phase reproducibility is essential for deterministic external injection of particles to be accelerated., Comment: Letter and Supplemental Material, 6 figures, 8 pages

Published

2021

44. The response of different types of TL lithium fluoride detectors to high-energy mixed radiation fields

Author

Obryk, B., Bilski, P., Budzanowski, M., Fuerstner, M., Ilgner, C., Jaquenod, F., Olko, P., Puchalska, M., and Vincke, H.

Published

2008

45. Measurement and calculation of high-energy neutron spectra behind shielding at the CERF 120 GeV/c hadron beam facility

Author

Nakao, N., Taniguchi, S., Roesler, S., Brugger, M., Hagiwara, M., Vincke, H., Khater, H., Prinz, A.A., Rokni, S.H., and Kosako, K.

Published

2008

46. Detailed study of the distribution of activation inside the magnet coils of a compact PET cyclotron

Author

Bonvin, V., primary, Bochud, F., additional, Damet, J., additional, Theis, C., additional, Vincke, H., additional, and Geyer, R., additional

Published

2021

47. Radiation safety aspects of the linac coherent light source project at [formula omitted]

Author

Rokni, S.H., Fassò, A., Mao, S., and Vincke, H.

Published

2006

48. A neutron dose rate monitor for high energies

Author

Klett, A., Mayer, S., Theis, C., and Vincke, H.

Published

2006

49. Comparison of air fluorescence and ionization measurements of EM shower depth profiles: Test of a UHECR detector technique

Author

Belz, J., Cao, Z., Huentemeyer, P., Jui, C.C.H., Martens, K., Matthews, J., Maestas, M., Smith, J., Sokolsky, P., Springer, R.W., Thomas, J., Thomas, S., Chen, P., Field, C., Hast, C., Iverson, R., Ng, J.S.T., Odian, A., Reil, K., Vincke, H., Walz, D., Goldammer, A., Guest, D., Thomson, G., Chang, F.-Y., Chen, C.-C., Chen, C.-W., Huang, M.A., Hwang, W.-Y.P., and Lin, G.-L.

Published

2006

50. Radiation safety analysis for the experimental hutches at the Linac coherent light source at SLAC

Author

Mao, X.S., Rokni, S.H., and Vincke, H.

Published

2006