Your search keyword '"Andrea Pisent"' showing total 8 results

1. Integration of 175-MHz LIPAc RF System and RFQ Linac for Beam Commissioning

Author

David Regidor, Atsushi Kasugai, Francesco Grespan, Francesco Scantamburlo, Keitaro Kondo, Masayoshi Sugimoto, Keishi Sakamoto, Takahiro Shinya, Michele Comunian, Sunao Maebara, Dominique Gex, Luca Bellan, Yosuke Hirata, Hitoshi Kobayashi, Yoshito Shimosaki, Ken Takayama, Tomoya Akagi, Takashi Ebisawa, Loris Antoniazzi, Ivan Moya, Hervé Dzitko, Puri Mendez, Antti Jokinen, Andrea Pisent, Takahide Nakayama, M. Weber, I. Kirpitchev, Joaquin Molla, Naoya Kubo, A. Palmieri, Philippe Cara, Cristina la de Morena, K. Hayashi, Maurizio Montis, Enrico Fagotti, and Alvaro Marchena

Subjects

Physics, Nuclear and High Energy Physics, business.industry, RF power amplifier, Circulator, Condensed Matter Physics, 01 natural sciences, Linear particle accelerator, 010305 fluids & plasmas, Power (physics), Optics, Radio-frequency quadrupole, 0103 physical sciences, Radio frequency, business, Electrical impedance, Beam (structure)

Abstract

The eight-chain RF system and radio frequency quadrupole (RFQ) linac were successfully integrated at the facility of the Linear IFMIF Prototype Accelerator (LIPAc). We achieved an unprecedented high current deuteron beam up to 55 mA in pulse operation ( $300~\mu \text{s}$ , 1 Hz). The keys of the success were (1) understanding reflected power from RFQ to RF system, (2) tuning each RF chain individually, (3) intensive RF conditioning for holding the stable RF power in the RFQ, and (4) optimizing the beam loading compensation control. Interestingly, the reflection at the breakdown in RF conditioning was higher than an estimation and reached up to 600 kW so far. In order to avoid damage on tetrodes by the high reflection, the impedance of each circulator was accurately adjusted.

Published

2020

2. Status and future developments of the Linear IFMIF Prototype Accelerator (LIPAc)

Author

Philippe Cara, Atsushi Kasugai, Kotaro Kondo, Guy Phillips, Hervé Dzitko, V. Massaut, A. Facco, Joaquin Molla, Keishi Sakamoto, Dominique Gex, Andrea Pisent, S. Chel, Masayoshi Sugimoto, Yann Carin, Koichi Hasegawa, Commissariat à l'énergie atomique et aux énergies alternatives (CEA), and LIPAc Unit Team

Subjects

particle accelerator, Computer science, Nuclear engineering, [PHYS.PHYS.PHYS-ACC-PH]Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph], Fusion materials, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, law.invention, law, 0103 physical sciences, Energy spectrum, IFMIF, General Materials Science, Neutron, Beam dump, 010306 general physics, beam operation, Civil and Structural Engineering, Mechanical Engineering, High intensity, Fusion power, High energy beam, Nuclear Energy and Engineering, LIPAc, Cryomodule, Neutron source

Abstract

International audience; LIPAc is the Linear IFMIF Prototype Accelerator developed within the framework of the IFMIF project under the Broader Approach (BA) agreement signed between EURATOM and the Japanese Government in 2007. The IFMIF accelerator aims to provide an accelerator-based D-Li neutron source to produce high intensity neutron fluxes with appropriate energy spectrum in order to characterize materials envisioned for future fusion reactors. Because the IFMIF accelerator has to reach unprecedented performances, the feasibility is being tested through the design, manufacturing, installation, commissioning and testing activities of a 1:1-scale prototype accelerator, namely LIPAc, from the injector to the first cryomodule together with the High Energy Beam Transport line and the High Power Beam Dump. After outstanding results obtained in 2019, the LIPAc project has entered 2020 in the preparation of the third commissioning stage, i.e., validation in continuous-wave mode of the complete accelerator up to 5 MeV with its final beam dump. The validation until the nominal energy of 9 MeV will be made after the completion of cryomodule assembly. After a brief overview of the goals already achieved in the framework of the IFMIF/EVEDA program, this paper will present a synthesis of the results that have been obtained so far with the LIPAc accelerator as well as the future developments planned beyond 2020.

Published

2021

3. Status of the RFQ linac installation and conditioning of the Linear IFMIF Prototype Accelerator

Author

Toshihiko Kitano, Antonio Palmieri, P. Mereu, M. Weber, Keishi Sakamoto, Yosuke Hirata, Ivan Moya, P. Mendez, Giuseppe Pruneri, I. Kirpitchev, Antti Jokinen, Andrea Pisent, Loris Antoniazzi, Maurizio Montis, Francesco Grespan, Alvaro Marqueta, Takashi Ebisawa, Sunao Maebara, Keitaro Kondo, Ryo Ichimiya, Dominique Gex, Luca Bellan, Francesco Scantamburlo, Enrico Fagotti, R. Heidinger, Juan Knaster, Masayoshi Sugimoto, K. Kasugai, Takahiro Shinya, David Regidor, Philippe Cara, Tomoya Akagi, Damiano Bortolato, and C. de la Morena

Subjects

Nuclear and High Energy Physics, Materials science, 010308 nuclear & particles physics, Materials Science (miscellaneous), Nuclear engineering, RF power amplifier, Fusion power, Feedback loop, 01 natural sciences, lcsh:TK9001-9401, Linear particle accelerator, 010305 fluids & plasmas, Power (physics), Nuclear Energy and Engineering, Radio-frequency quadrupole, Electric field, 0103 physical sciences, lcsh:Nuclear engineering. Atomic power, Beam (structure)

Abstract

The Radio Frequency Quadrupole (RFQ) linac and 1.6 MW RF power system of the Linear IFMIF Prototype Accelerator (LIPAc) facility in the International Fusion Energy Research Center (IFERC) in Rokkasho (Japan) has been installed and conditioned. During the assembly and tuning process, the RFQ cavity was protected with a temporary tent from the potential deterioration of performance caused by dust. The vacuum in the cavity was improved through the 100 °C baking process of the cavity. The high power test of the 175 MHz RF systems up to 200 kW in CW for each of the eight RF chains was performed for checking its stable output reproducibility in Japan, before connecting 9–3/16 inch coaxial transmission lines from the RF chains to the RF input couplers of the cavity. It was confirmed that the eight RF chains provided the balanced RF power to the single RFQ cavity in-phase using a feedback loop and a synchronization system. The peak power in the cavity achieved 150 kW in the pulsed mode, which corresponds approximately to the required electric field to accelerate proton beam. Such RF conditioning process is ongoing to achieve 600 kW approximately required for deuteron beam commissioning planned in 2018.

Published

2018

4. Development and installation of a radio frequency quadrupole cooler test

Author

Massimiliano Romé, Mario Maggiore, Alessio Galatà, Andrea Pisent, Lorenzo Pranovi, Luca Bellan, Francesco Cavaliere, M. Cavenago, Giancarlo Maero, Michele Comunian, A.M. Porcellato, and N. Panzeri

Subjects

010302 applied physics, Materials science, Ion beam, business.industry, Buffer gas, 01 natural sciences, Ion source, 010305 fluids & plasmas, Magnetic field, law.invention, Optics, Radio-frequency quadrupole, law, 0103 physical sciences, Physics::Accelerator Physics, Thermal emittance, Radio frequency, Faraday cage, business, Instrumentation

Abstract

A Radio Frequency Quadrupole Cooler (RFQC) prototype was adapted for insertion into a high uniformity magnetic field, with Bz up to 0.2 T, to improve radial confinement. While the RFQC purpose is to reduce (by gas collisions) the energy spread and emittance of a beam of radioactive nuclei, to finely select ion mass in nuclear physics, the prototype is tested in a setup including a stable ion source, a pepper pot emittance meter, and two Faraday cups; this makes a precise characterization of the RFQC feasible. The ion extraction was studied in detail by simulations, both to match it to the emittance meter granularity and to verify the effect of the typical nonuniformity of the longitudinal electric field Ez inside the RFQC; an average motion description (including friction force from gas collisions) was used, introducing the ballistic and diffusive regimes. With a preliminary optimization of the electrode shape, buffer gas pressure pg, and radio frequency voltage, the ion beam can be extracted with a significant cooling margin.

Published

2019

5. Validation of the Linear IFMIF Prototype Accelerator (LIPAc) in Rokkasho

Author

Takahiro Shinya, Guy Phillips, S. Chel, Beatriz Brañas, Michele Comunian, Saerom Kwon, Benoit Bolzon, Angel Rodriguez, Ivan Podadera, Philippe Cara, Enrico Fagotti, Dominique Gex, David Jimenez, Luca Bellan, Jacques Marroncle, Tomoya Akagi, Francesco Grespan, R. Heidinger, Antti Jokinen, Andrea Pisent, Nicolas Bazin, Alvaro Marchena, Hervé Dzitko, Keishi Sakamoto, Alvaro Marqueta, Purificación Méndez, Sunao Maebara, Francesco Scantamburlo, Takashi Ebisawa, Daniel Gavela, A. Facco, David Regidor, Ivan Moya, Atsushi Kasugai, Kohki Kumagai, Yosuke Hirata, A. Palmieri, Jesus Castellanos, Yann Carin, Juan Knaster, M. Weber, Rodrigo Varela, Keitaro Kondo, Masayoshi Sugimoto, Yoshito Shimosaki, F. Arranz, Oriol Nomen, Giuseppe Pruneri, and Joaquin Molla

Subjects

Materials science, Mechanical Engineering, Nuclear engineering, RF power amplifier, International Fusion Materials Irradiation Facility, Injector, Fusion power, 01 natural sciences, Linear particle accelerator, 010305 fluids & plasmas, law.invention, Nuclear Energy and Engineering, law, Duty cycle, 0103 physical sciences, General Materials Science, Beam dump, 010306 general physics, Beam (structure), Civil and Structural Engineering

Abstract

For the development of the International Fusion Materials Irradiation Facility (IFMIF) aiming at material tests for fusion power plants, the construction of the Linear IFMIF Prototype Accelerator (LIPAc) has been conducted at Rokkasho, Japan under the Broader Approach Agreement. The commissioning of LIPAc has been progressing significantly. The world most powerful RFQ successfully accelerated proton beam of 58 mA, and an important project milestone of the acceleration of deuteron beam to 5 MeV with the beam current of 125 mA in pulse mode was successfully achieved. The result proves the validity of the present RFQ design. The adjustment and tuning of the RF power system and the injector for enabling an operation at maximum performances played an important role in achieving this result. For the next step, the preparation of the high duty cycle operation of RFQ is underway. The installation of the HEBT (High Energy Beam Transport line) and the beam dump accepting 1 MW, CW beam, has been completed and a new beam transport line is under manufacturing. Also the assembly of the Superconducting RF (SRF) linac to accelerate the beam up to 9 MeV started in a clean room in Rokkasho.

Published

2020

6. ADIGE: The Radioactive Ion Beam Injector of the SPES Project

Author

Luca Bellan, G. Bisoffi, Andrea Pisent, Michele Comunian, A. Palmieri, L Martin, M.F. Moisio, Alessio Galatà, C. Roncolato, and G. Prete

Subjects

010302 applied physics, Radioactive ion beams, History, Ion beam, Nuclear engineering, Injector, 04 Hadron Accelerators, 01 natural sciences, Computer Science Applications, Education, law.invention, Accelerator Physics, law, 0103 physical sciences, Environmental science, 010306 general physics

Abstract

The Selective Production of Exotic Species (SPES) project is presently under development at INFN-LNL: aim of this project is the production, ionization and post-acceleration of radioactive ions to perform forefront research in nuclear physics. An ECR-based charge breeder (SPES-CB) will allow post-acceleration of radioactive ions: in particular, the SPES-CB has been designed and developed by LPSC of Grenoble, based on the Phoenix booster. It will be equipped with a complete test bench totally integrated with the SPES beam line: this part of the post-accelerator, together with the newly designed RFQ, composes the so-called ADIGE injector for the superconducting linac ALPI. The injector will employ a unique Medium Resolution Mass Spectrometer (MRMS, R=1/1000), mounted downstream the SPES-CB, in order to avoid the typical drawback of the ECR-based charge breeding technique, that is the beam contamination. This contribution describes the ADIGE injector, with particular attention to the analysis of possible contaminations and the performances expected for the MRMS, showing the beam dynamics calculations for a reference radioactive beam., Proceedings of the 8th Int. Particle Accelerator Conf., IPAC2017, Copenhagen, Denmark

Published

2017

7. 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

8. The SPES radioactive ion beam project of LNL: status and perspectives

Author

Mario Maggiore, J. Vasquez, G. Bassato, Andrea Pisent, R. Pegoraro, M. Calderolla, A. Russo, P. F. Mastinu, A. Andrigetto, Mattia Manzolaro, G. Prete, Alessio Galatà, M. Rossignoli, M. Giacchini, S. Canella, Luciano Calabretta, J. Valiente, D. Benini, M. Rigato, D. Zafiropoulos, Michele Comunian, Stefano Corradetti, S. Zanella, Juan Esposito, Daniele Scarpa, P. Favaron, A.M. Porcellato, A. Monetti, J. Wyss, C. Roncolato, M. Lollo, J. Bermudez, Alessandra Lombardi, Giacomo de Angelis, D. Maniero, G. Bisoffi, L. Sarchiapone, and F. Gramegna

Subjects

Nuclear reaction, Engineering, Ion beam, Proton, 010308 nuclear & particles physics, business.industry, Fission, Physics, QC1-999, Nuclear Theory, Cyclotron, 01 natural sciences, Engineering physics, Linear particle accelerator, law.invention, Nuclear physics, law, 0103 physical sciences, Physics::Accelerator Physics, Neutron, Nuclear Experiment, 010306 general physics, business, Beam (structure)

Abstract

A new Radioactive Ion Beam (RIB) facility (SPES) is presently under construction at the Legnaro National Laboratories of INFN. The SPES facility is based on the ISOL method using an UCx Direct Target able to sustain a power of 8 kW. The primary proton beam is provided by a high current Cyclotron accelerator with energy of 35-70 MeV and a beam current of 0.2-0.7 mA. Neutron-rich radioactive ions are produced by proton induced fission on an Uranium target at an expected fission rate of the order of 1013 fissions per second. After ionization and selection the exotic isotopes are re-accelerated by the ALPI superconducting LINAC at energies of 10A MeV for masses in the region A=130 amu. The expected secondary beam rates are of the order of 107 - 109 pps. Aim of the SPES facility is to deliver high intensity radioactive ion beams of neutron rich nuclei for nuclear physics research as well as to be an interdisciplinary research centre for radio-isotopes production for medicine and for neutron beams.

Published

2016