Your search keyword '"Philippe Cara"' showing total 4 results

1. Neutron production measurement in the 125 mA 5 MeV deuteron beam commissioning of Linear IFMIF Prototype Accelerator (LIPAc) RFQ

Author

A. Palmieri, Tomoya Akagi, Ivan Podadera, Francesco Grespan, Michele Comunian, Saerom Kwon, Philippe Cara, Enrico Fagotti, Francesco Scantamburlo, Kai Masuda, Joaquin Molla, Takahiro Shinya, Angel Rodriguez, Hervé Dzitko, Masayoshi Sugimoto, Shimosaki Yoshito, Yann Carin, Keitaro Kondo, Keishi Sakamoto, Dominique Gex, Luca Bellan, Andrea Pisent, Ivan Moya, Atsushi Kasugai, D. Jiménez-Rey, and Kohki Kumagai

Subjects

Physics, Nuclear and High Energy Physics, High energy, Acceleration, Deuterium, Nuclear engineering, Beam commissioning, Neutron, High current, Activation method, Condensed Matter Physics, Beam (structure)

Abstract

The validation of the Linear IFMIF Prototype Accelerator (LIPAc) is being conducted in Rokkasho Fusion Institute of QST, Aomori, Japan. The beam commissioning of the novel LIPAc RFQ has been progressing significantly, and the acceleration of the world highest current deuteron beam of 125 mA to 5 MeV (1 ms, 1 Hz pulsed beam) was achieved for the 1st time in July 2019. This study is devoted to evaluating the amount of beam loss during the high current acceleration phase by measuring the neutron produced by the interaction of the beam with accelerator components so as to verify the accelerator design. The foil activation method and the 3He neutron probes were utilized. It turned out that there was no significant trace of unexpected beam loss at the high energy section of the RFQ and the Medium Energy Beam Transport (MEBT) section.The measurement using the 3He neutron probes provided an evidence that the beam loss was well controlled in the RFQ cavity as designed. This study concludes that the LIPAc RFQ as well as MEBT is working well as predicted by the design calculation, and its concept is successful.

Published

2021

2. Overview of the IFMIF/EVEDA project

Author

Gioacchino Miccichè, Hiroo Kondo, S. Ohira, Keishi Sakamoto, Yoshikazu Okumura, S. Chel, Tomohiro Furukawa, P. Garin, V. Massaut, Takuji Kanemura, Philippe Cara, Joaquin Molla, Frederik Arbeiter, Takehiko Yokomine, A. Facco, P. Favuzza, Atsushi Kasugai, R. Heidinger, Angel Ibarra, Eiichi Wakai, H. Matsumoto, Juan Knaster, Masayoshi Sugimoto, Micciche, G., and Favuzza, P.

Subjects

deuteron, Nuclear and High Energy Physics, Materials science, Condensed Matter Physics, 01 natural sciences, accelerator-driven systems, 010305 fluids & plasmas, neutron source, liquid metal, lithium, IFMIF, liquid metals, 0103 physical sciences, 010306 general physics

Abstract

in turn, the commissioning of the 5 MeV beam is due to start during 2017. The D+ beam through the superconducting cavities is expected to be achieved within the Broader Approach Agreement time frame with the superconducting cryomodule being assembled in Rokkasho. The realisation of a fusion-relevant neutron source is a necessary step for the successful development of fusion. The ongoing success of the IFMIF/EVEDA involves ruling out concerns about potential technical showstoppers which were raised in the past. Thus, a situation has emerged where soon steps towards constructing a Li(d,xn) fusion-relevant neutron source could be taken, which is also justified in the light of costs which are marginal to those of a fusion plant. © 2017 IAEA, Vienna., IFMIF, the International Fusion Materials Irradiation Facility, is presently in its engineering validation and engineering design activities (EVEDA) phase under the Broader Approach Agreement. The engineering design activity (EDA) phase was successfully accomplished within the allocated time. The engineering validation activity (EVA) phase has focused on validating the Accelerator Facility (AF), the Target Facility and the Test Facility (TF) by constructing prototypes. The ELTL at JAEAc, Oarai successfully demonstrated the long-term stability of a Li flow under the IFMIF's nominal operational conditions keeping the specified free-surface fluctuations below 1 mm in a continuous manner for 25 d. A full-scale prototype of the high flux test module (HFTM) was successfully tested in the HELOKA loop (KIT, Karlsruhe), where it was demonstrated that the irradiation temperature can be set individually and kept uniform. LIPAc, designed and constructed in European labs under the coordination of F4E, presently under installation and commissioning in the Rokkasho Fusion Institute, aims at validating the concept of IFMIF accelerators with a D+ beam of 125 mA continuous wave (CW) and 9 MeV. The commissioning phases of the H+/D+ beams at 100 keV are progressing and should be concluded in 2017

Published

2017

3. Deuteron beam commissioning of the linear IFMIF prototype accelerator ion source and low energy beam transport

Author

S. Chel, Takahiro Shinya, Andrea Pisent, Philippe Cara, Michele Comunian, Giuseppe Pruneri, Tomoya Akagi, F. Sénée, Akira Ihara, Juan Knaster, Benoit Bolzon, Ryo Ichimiya, Hervé Dzitko, F. Gérardin, Atsushi Kasugai, M. Komata, Kotaro Kondo, Yoshikazu Okumura, Alvaro Marqueta, Raphael Gobin, Nicolas Chauvin, Keishi Sakamoto, Francis Harrault, Toshihiko Kitano, Francesco Scantamburlo, Pierre-Yves Beauvais, Dominique Gex, Luca Bellan, R. Heidinger, Koichi Nishiyama, Masayoshi Sugimoto, and E. Fagotti

Subjects

Accelerator physics, Nuclear and High Energy Physics, Materials science, Nuclear engineering, International Fusion Materials Irradiation Facility, Injector, Condensed Matter Physics, 01 natural sciences, Ion source, Electron cyclotron resonance, 010305 fluids & plasmas, law.invention, Deuterium, law, 0103 physical sciences, Quadrupole, 010306 general physics, Beam (structure)

Abstract

During the EVEDA (engineering validation and engineering design activities) phase of the International Fusion Materials Irradiation Facility (IFMIF) project, a 125 mA/9 MeV linear prototype accelerator (LIPAc) has to be built, tested and operated in Rokkasho-mura (Japan). Involved in this project for several years, CEA-Saclay designed the injector of this accelerator which is composed of an electron cyclotron resonance ion source, delivering a 140 mA deuteron beam at 100 keV, and a low energy beam transport (LEBT) line to match the beam for the injection into the radio-frequency quadrupole. In this paper, the components of the LIPAc injector are described. The commissioning of the ion source and LEBT with beam started in November 2014. The different phases of the commissioning are explained and some noticeable experimental results obtained with a beam at 100 keV are presented.

Published

2019

4. IFMIF: overview of the validation activities

Author

Tomohiro Furukawa, Masayoshi Sugimoto, P. Favuzza, Hisashi Serizawa, Eiichi Wakai, Juan Knaster, H. Suzuki, Angel Ibarra, F. Groeschel, H. Matsumoto, Frederik Arbeiter, R. Heidinger, Philippe Cara, A. Mosnier, and Favuzza, P.

Subjects

Nuclear and High Energy Physics, High flux, Engineering, Test facility, business.industry, Rapid construction, Nuclear engineering, Full scale, International Fusion Materials Irradiation Facility, Gas cooling, Condensed Matter Physics, business, Engineering design process

Abstract

The IFMIF/EVEDA project under the Broader Approach Agreement between Japan and EU aims at allowing a rapid construction phase of IFMIF in due time. The three main facilities, (1) the Accelerator Facility, (2) the Target Facility and (3) the Test Facility, are the subject of validation activities that include the construction of either full scale prototypes or smartly devised scaled down facilities that will allow a straightforward extrapolation to IFMIF needs. The installation of a Linac of 1.125 MW (125 mA and 9 MeV) of deuterons started in March 2013 in Rokkasho. The world largest liquid Li test loop is running in Oarai with an ambitious experimental programme for the years ahead. A full scale high flux test module that will house sim 1000 small specimens developed jointly in Europe and Japan has been constructed in Germany together with its He gas loop. A full scale medium flux test module to carry out on-line creep measurement has been constructed in Switzerland., 著者所属: 日本原子力研究開発機構(JAEA)

Published

2013