Your search keyword '"Raphael Gobin"' showing total 42 results

1. Beam diagnostics of an ECR ion source on LIPAc injector for prototype IFMIF beam accelerator

Author

Giuseppe Pruneri, Nicolas Chauvin, Francesco Scantamburlo, Masayoshi Sugimoto, Ivan Podadera, Yoshikazu Okumura, Philippe Cara, Toshihiko Kitano, Keitaro Kondo, Atsushi Kasugai, Benoit Bolzon, R. Heidinger, Franck Senée, Ryo Ichimiya, Keishi Sakamoto, Raphael Gobin, Tomoya Akagi, Rodrigo Varela, Koichi Nishiyama, Akira Ihara, Takahiro Shinya, David Jimenez, Hervé Dzitko, Francis Harrault, Masao Komata, Alvaro Marqueta, Pierre-Yves Beauvais, S. Chel, Jose Miguel Carmona, and Juan Knaster

Subjects

010302 applied physics, Materials science, Spectrometer, Mechanical Engineering, Nuclear engineering, Injector, Fusion power, 01 natural sciences, Ion source, Linear particle accelerator, 010305 fluids & plasmas, law.invention, Nuclear Energy and Engineering, law, 0103 physical sciences, General Materials Science, Beam dump, Beam emittance, Beam (structure), Civil and Structural Engineering

Abstract

The IFMIF accelerator facility consists of 2 identical linacs, each accelerating a 125 mA CW deuteron beam up to the energy of 40 MeV. In order to reach these unprecedented performances, the Linear IFMIF Prototype Accelerator (LIPAc) is under installation and commissioning at the International Fusion Energy Research Centre (IFERC) in Rokkasho, Japan, in the framework of the IFMIF/EVEDA project, which is part of the Broader Approach (BA) agreement between Japan and EU. The accelerator is designed to validate components up to 125 mA CW deuteron beam at 9 MeV. The accelerator components of LIPAc have been designed and manufactured mainly by European Institutes. The injector and superconducting linac, RFQ, MEBT, Diagnostics Plate, HEBT and beam dump have been developed respectively by CEA-Saclay, INFN-Legnaro and CIEMAT-Madrid and were delivered to Rokkasho between 2013 and 2016. The commissioning of the injector with beam started in November 2014. This paper dealt with the experimental data obtained with the beam diagnostics of the injector. The electrical measurements of the beam intensity on the beam stopper were compared with calorimetric measurements. The beam profiles measured with a CCD camera and a custom image-intensified CID camera are also addressed. The analysis of beam emittance and ion species fractions from data obtained with an Allison scanner is described and the results of species fraction measurements are compared with those obtained by using a deported spectrometer. Finally, the analysis of beam space potential from data obtained with a 4-Grid analyser is presented.

Published

2018

2. LIPAc personnel protection system for realizing radiation licensing conditions on injector commissioning with deuteron beam

Author

Takahiro Narita, Atsushi Kasugai, Raphael Gobin, Hironao Sakaki, Koichi Nishiyama, Hiroki Takahashi, Alvaro Marqueta, and Toshiyuki Kojima

Subjects

Project commissioning, Computer science, Mechanical Engineering, Nuclear engineering, Injector, Radiation, Protection system, 01 natural sciences, Deuterium ions, 010305 fluids & plasmas, law.invention, Nuclear facilities, Nuclear Energy and Engineering, law, 0103 physical sciences, General Materials Science, 010306 general physics, Beam (structure), Civil and Structural Engineering

Abstract

The performance validation of the Linear IFMIF Prototype Accelerator (LIPAc), up to the energy of 9 MeV deuteron beam with 125 mA continuous wave (CW), is planned in Rokkasho, Japan. There are three main phases of LIPAc performance validation: Injector commissioning, RFQ commissioning and LIPAc commissioning. Injector commissioning was started by H+ and D+ beam. To apply the radiation licensing for the Injector commissioning, the entering/leaving to/from accelerator vault should be under control, and access to the accelerator vault has to be prohibited for any person during the beam operation. The Personnel Protection System (PPS) was developed to adapt the radiation licensing conditions. The licensing requests that PPS must manage the accumulated D+ current. So, to manage the overall D+ beam time during injector operation, Pulse Duty Management System (PDMS) was developed as a configurable subsystem as part of the PPS. The PDMS was tested during H+ beam (as simulated D+) operation, to confirm that it can handle the beam inhibit from Injector before the beam accumulation is above the threshold value specified in the radiation licensing condition. In this paper, the design and configuration of these systems and the result of the tests are presented.

Published

2016

3. RFQ Commissioning of Linear IFMIF Prototype Accelerator (LIPAc)

Author

Marqueta, Alvaro, Andrea, Pisent, Antonio, Palmieri, Bolzon, Benoit, Cristina, De La Morena, Damiano, Bortolato, David, Jimenez-Rey, David, Regidor, Enrico, Fagotti, Dominique, Gex, Francescco, Scantamburlo, Francesco, Grespan, Pruneri, Giuseppe, Guy, Phillips, Herve, Dzitko, Igor, Kirpitchev, Jacques, Marroncle, Joaquin, Molla, Loris, Antoniazzi, Maurizio, Montis, Michele, Comunian, Moises, Weber, Nicolas, Bazin, Nicolas, Chauvin, Philippe, Abbon, Pierre-Yves, Beauvais, Purificacion, Mendez, Raphael, Gobin, Roland, Heidinger, Stephan, Chel, Alvaro Marqueta, Benoit Bolzon, and Giuseppe Pruneri

Abstract

The IFMIF project aiming at material tests for a future fusion DEMO reactor is under the EVEDA phase in the BA Agreement of fusion program between Japan and EU. As the accelerator activity, the installation and commissioning of the Linear IFMIF Prototype Accelerator (LIPAc) is at the second stage of demonstration of the feasibility of the low energy section of an IFMIF deuteron accelerator up to 9 MeV with a beam current of 125 mA, CW. The installation of injector, RFQ, MEBT, D-Plate and LPBD for LIPAc with 8 coaxial high-power transmission lines and RF power system was just done in 2017 at Rokkasho, Japan. After that, the RF conditioning of RFQ for beam commissioning is underway. The beam commissioning of RFQ with H+/D+ and the acceleration demonstration up to 5MeV-125mA-0.1% duty cycle with D+ will be done.

Published

2018

4. Development of calorimetry methodology for beam current measurement of the Linear IFMIF Prototype Accelerator (LIPAc)

Author

Kotaro Kondo, Giuseppe Pruneri, Koichi Nishiyama, Keishi Sakamoto, Benoit Bolzon, Raphael Gobin, Ryo Ichimiya, Sunao Maebara, Pierre-Yves Beauvais, Masayoshi Sugimoto, Yoshikazu Okumura, Toshihiko Kitano, Akira Ihara, Juan Knaster, Y. Ikeda, Francesco Scantamburlo, Takahiro Shinya, Yosuke Hirata, Alvaro Marqueta, Atsushi Kasugai, Commissariat à l'énergie atomique et aux énergies alternatives (CEA), and LIPAc Integrated Project Team

Subjects

Materials science, Nuclear engineering, [PHYS.PHYS.PHYS-ACC-PH]Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph], Accelerator, 01 natural sciences, 7. Clean energy, Secondary electrons, 010305 fluids & plasmas, Beam current, 0103 physical sciences, Water cooling, IFMIF, General Materials Science, [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det], Civil and Structural Engineering, 010302 applied physics, Observational error, Mechanical Engineering, EVEDA, Calorimetric, Volumetric flow rate, Nuclear Energy and Engineering, LIPAc, Duty cycle, Heat transfer, Continuous wave, Physics::Accelerator Physics, Beam (structure)

Abstract

The goal of LIPAc (Linear IFMIF Prototype Accelerator) is to achieve a 125 mA, 9 MeV, CW (continuous wave, i.e. 100% duty cycle) deuteron beam with an average beam power of 1.125 MW. In the beam current measurement, it is considered that calorimetric measurement is advantageous for high current and CW operations since it is not subject to secondary electrons, etc. In calorimetric measurements, it is necessary to measure the temperature rise of the cooling water as accurately as possible. We applied this method to LIPAc proton beams at the Beam Stop unit. In order to check the reliability, we inserted a heater in the cooling loop as a heat source and obtained correlation between the applied and measured power, which was found to be 1.0. Moreover, using this heater, accuracy of this measurement with respect to the flow rate of the cooling water was investigated. Due to heat transfer and the fluctuations of water temperature, etc., there is a range of flow rates in which the measurement error can be minimized with our calorimetric measurement system.

Published

2018

5. Hardware availability calculations and results of the IFMIF accelerator facility

Author

Javier Abal, Fabienne Orsini, Angel Ibarra, Enrico Fagotti, Ivan Podadera, Jose Manuel Arroyo, M. Weber, J. Dies, Carlos Tapia, Francesco Grespan, Enric Bargalló, Alfredo de Blas, Raphael Gobin, Pierre-Yves Beauvais, Joaquin Molla, Universitat Politècnica de Catalunya. Departament de Física i Enginyeria Nuclear, and Universitat Politècnica de Catalunya. NERG - Grup de Recerca d'Enginyeria Nuclear

Subjects

Energies::Energia nuclear [Àrees temàtiques de la UPC], Fault tree analysis, Design modification, business.industry, Computer science, Mechanical Engineering, Design information, Principal (computer security), Maintainability, Accelerator, Availability, International Fusion Materials Irradiation Facility, RAMI, Reliability, Energies::Energia nuclear::Reactors nuclears de fusió [Àrees temàtiques de la UPC], Nuclear Energy and Engineering, IFMIF, Nuclear fusion, Fusió nuclear, General Materials Science, Unavailability, business, Computer hardware, Reliability (statistics), Civil and Structural Engineering

Abstract

Hardware availability calculations have been done individually for each system of the deuteron accelerators of the International Fusion Materials Irradiation Facility (IFMIF). The principal goal of these analyses is to estimate the availability of the systems, compare it with the challenging IFMIF requirements and find new paths to improve availability performances.; Major unavailability contributors are highlighted and possible design changes are proposed in order to achieve the hardware availability requirements established for each system. In this paper, such possible improvements are implemented in fault tree models and the availability results are evaluated.; The parallel activity on the design and construction of the linear IFMIF prototype accelerator (LIPAc) provides detailed design information for the RAMI (reliability, availability, maintainability and inspectability) analyses and allows finding out the improvements that the final accelerator could have. Because of the R&D behavior of the LIPAc, RAMI improvements could be the major differences between the prototype and the IFMIF accelerator design.

Published

2014

6. 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

7. RAMI analyses of the IFMIF accelerator facility and first availability allocation between systems

Author

David Regidor, Angel Ibarra, J. Calvo, Javier Abal, Enric Bargalló, Ivan Podadera, Jose Manuel Arroyo, A. de Blas, M. Weber, Carlos Tapia, Gonzalo Martínez, J. Dies, Joaquin Molla, A. Giralt, Pierre-Yves Beauvais, F. Orsini, and Raphael Gobin

Subjects

Fault tree analysis, Downtime, Computer science, business.industry, Mechanical Engineering, Maintainability, International Fusion Materials Irradiation Facility, Linear particle accelerator, Reliability engineering, Software, Nuclear Energy and Engineering, General Materials Science, Unavailability, business, Reliability (statistics), Civil and Structural Engineering

Abstract

An analysis in terms of Reliability, Availability, Maintainability and Inspectability (RAMI) has been done for each system (Injector, MEBT, SRF Linac, RF system⿦) of the deuteron accelerators of the International Fusion Materials Irradiation Facility (IFMIF). The goal of these analyses is to estimate the availability of the accelerator facility based on the current design in order to compare it with the high IFMIF availability requirements. A first availability allocation between accelerator systems was performed to quantify the improvement demanded in terms of RAMI to achieve such requirements. These studies highlight the critical parts and parameters that most likely can have an impact on downtime. Individual fault tree analysis was done for each system of the accelerator with the software RiskSpectrum® PSA Professional. With such model, a deep analysis was done and therefore major unavailability contributors for each system were presented. Statistical analyses were developed to evaluate time dependency, parameters and events importance, sensitivities and uncertainties. Results gave indications for possible improvements, whenever feasible, for each accelerator system. These studies have been performed in collaboration between system designers and RAMI experts enabling the creation of RAMI models that reflect the current accelerator design. The parallel activity on the design and construction of the Linear IFMIF Prototype Accelerator (LIPAc) provides detailed design information and allows the finding of the improvements that the final accelerator could have. Because of the R&D character of the LIPAc, design improvements based on the results of the RAMI analysis could be the major differences between LIPAc and the IFMIF accelerator design.

Published

2013

8. Two approaches for H−ion production with 2.45 GHz ion sources

Author

O. Delferrière, J. Breton, P. Auvray, M. Bacal, A. A. Ivanov, F. Harrault, O. Tuske, Panagiotis Svarnas, and Raphael Gobin

Subjects

Nuclear and High Energy Physics, Materials science, Ion beam, Spallation, Ion current, Electron, Plasma, Atomic physics, Condensed Matter Physics, Ion source, Electron cyclotron resonance, Ion

Abstract

Over the last few years, the accelerator community requested the development of improved negative hydrogen ion sources. For spallation sources, like SNS or ESS, pulsed high intensity H− ion beams of a few tens of milliamperes, with a duty cycle close to 10%, are required. New facilities like CERN also ask for high performance negative ion beams. Since CEA undertook an electron cyclotron resonance (ECR)-based ion source programme, a European network devoted to high performance negative ion source development has been created.In this group, several laboratories developing 2.45 GHz ECR sources follow different approaches to increase the extracted ion current. At Saclay, with a solenoidal magnetic structure based on coils, close to 3 mA H− ion beam is now extracted in pulsed mode (2 ms/100 ms). A metallic biased grid separates the plasma bulk from the H− ion production zone and significantly improves the H− extracted current. At Ecole Polytechnique, the source Camembert III operates in continuous wave and pulsed modes. Photodetachment measurements in continuous wave mode show considerable H− ion density (109–1010 cm−3), whether the primary electrons are provided by filaments or small ECR modules inserted into the plasma chamber. Similarities and differences between the ECR-driven and the filamented source are discussed. Representative experimental results from the sources of the two laboratories as well as future plans are reported here.

Published

2006

9. Status of the Trasco Intense Proton Source and emittance measurements

Author

G. Ciavola, Luigi Celona, Raphael Gobin, R. Ferdinand, L. Andò, Santo Gammino, F. Chines, M. Presti, and X. H. Guo

Subjects

Nuclear physics, Physics, Proton, Thermal emittance, Operating voltage, Instrumentation, Beam (structure)

Abstract

The Trasco Intense Proton Source (TRIPS) was installed at INFN-LNS in May 2000 and has been fully operational since the Fall of 2000; now the source fulfills all the requirements of the TRASCO (Trasmutazione Scorie) project. The proton beam intensity easily exceeds 40 mA at the operating voltage of 80 kV. A set of emittance measurements was carried out for different source conditions and confirmed the simulations performed with the AXCEL code: in all the cases the rms normalized emittance is well lower than the value required for the injection into the RFQ (0.2 π mm mrad); the results will be shown and discussed. Finally a beam reliability of 99.8% has been found during a long run test lasting over 142 h.

Published

2004

10. Improvement of extraction system geometry with suppression of possible Penning discharge ignition

Author

Raphael Gobin, S. Nyckees, Olivier Tuske, Francis Harrault, and Olivier Delferrière

Subjects

Materials science, Physics::Plasma Physics, Equipotential, Cyclotron resonance, Physics::Accelerator Physics, Geometry, Plasma diagnostics, International Fusion Materials Irradiation Facility, Solenoid, Plasma, Beam emittance, Instrumentation, Ion source

Abstract

During the past two years, a new ECR 2.45 GHz type ion source has been developed especially dedicated to intense light ion injector project like IPHI (Injecteur Proton Haute Intensite), IFMIF (International Fusion Materials Irradiation Facility), to reduce beam emittance at RFQ entrance by shortening the length of the LEBT. This new ALISES concept (Advanced Light Ion Source Extraction System) is based on the use of an additional LEBT short length solenoid very close to the extraction aperture. The fringe field of this new solenoid produces the needed magnetic field to create the ECR resonance in the plasma chamber. Such geometry allows first putting the solenoid at ground potential, while saving space in front of the extraction to move the first LEBT solenoid closer and focus earlier the intense extracted beam. During the commissioning of the source in 2011–2012, ALISES has produced about 20 mA extracted from a 6 mm diameter plasma extraction hole at 23 kV. But the magnetic configuration combined to the new extraction system geometry led to important Penning discharge conditions in the accelerator column. Lots of them have been eliminated by inserting glass pieces between electrodes to modify equipotential lines with unfavorable ExB vacuum zones where particles were produced and trapped. To study Penning discharge location, several 3D calculations have been performed with OPERA-3D/TOSCA code to simulate the possible production and trapping of electrons in the extraction system. The results obtained on different sources already built have shown very good agreement with sparks location observed experimentally on electrodes. The simulations results as well as experimental measurements are presented and solutions to prevent possible Penning discharge in future source geometries are established.

Published

2014

11. International Fusion Materials Irradiation Facility injector acceptance tests at CEA/Saclay: 140 mA/100 keV deuteron beam characterization

Author

Franck Senée, S. Chel, H. Shidara, Yoshikazu Okumura, Nicolas Chauvin, Philippe Cara, P. Mattei, Olivier Delferrière, A. Mosnier, D. Bogard, Francis Harrault, and Raphael Gobin

Subjects

Nuclear physics, Physics, Beamline, law, Neutron flux, Thermal emittance, International Fusion Materials Irradiation Facility, Solenoid, Injector, Instrumentation, Beam (structure), Linear particle accelerator, law.invention

Abstract

In the framework of the ITER broader approach, the International Fusion Materials Irradiation Facility (IFMIF) deuteron accelerator (2 × 125 mA at 40 MeV) is an irradiation tool dedicated to high neutron flux production for future nuclear plant material studies. During the validation phase, the Linear IFMIF Prototype Accelerator (LIPAc) machine will be tested on the Rokkasho site in Japan. This demonstrator aims to produce 125 mA/9 MeV deuteron beam. Involved in the LIPAc project for several years, specialists from CEA/Saclay designed the injector based on a SILHI type ECR source operating at 2.45 GHz and a 2 solenoid low energy beam line to produce such high intensity beam. The whole injector, equipped with its dedicated diagnostics, has been then installed and tested on the Saclay site. Before shipment from Europe to Japan, acceptance tests have been performed in November 2012 with 100 keV deuteron beam and intensity as high as 140 mA in continuous and pulsed mode. In this paper, the emittance measurements done for different duty cycles and different beam intensities will be presented as well as beam species fraction analysis. Then the reinstallation in Japan and commissioning plan on site will be reported.

Published

2014

12. Study and preliminary results for a new type of ECR H− ions source

Author

K. Benmeziane, Raphael Gobin, R. Ferdinand, and Gerard Gousset

Subjects

Monte Carlo method, Cyclotron resonance, Code (cryptography), Particle-in-cell, Atomic physics, Current source, Instrumentation, Ion source, Computational physics, Power (physics), Ion

Abstract

With the passing of the years, the need has been growing to be able to build a high current source with a long lifetime. An H− ion production code has been developed to improve the understanding on this ion production. At the same time very promising experimentation is going on at CEA-Saclay on an ECR H− ion source. This code is split in two parts. A PIC 1D MCC 3D code (particle in cell in 1D Monte Carlo with collision in 3D) is in charge of establishing the electron energy distribution function (EEDF), which is later used in a fluid code. This second code calculates the chemistry of the H− ion production. The 2D configuration of the study obliges us to choose a PIC code instead of a Boltzmann one. Two important difficulties are considered. The first one is due to a very low pressure (under 10 mTorr) as it is common in H− production experiments. The second difficulty is to accurately inject the high power discharge (few-tenths kW), usually demanded for such sources. This condition often carries divergence...

Published

2004

13. Development of an H− ion source based on the electron cyclotron resonance plasma generator at CEA/Saclay

Author

Gerard Gousset, Olivier Delferrière, R. Ferdinand, Francis Harrault, Raphael Gobin, K. Benmeziane, and Joseph D. Sherman

Subjects

Materials science, Cyclotron resonance, Plasma, Atomic physics, Instrumentation, Fourier transform ion cyclotron resonance, Microwave, Electron cyclotron resonance, Ion source, Ion cyclotron resonance, Ion

Abstract

Electron cyclotron resonance (ECR) plasma generators have demonstrated their efficiency, reproducibility, and long lifetime for the production of light positive ions like protons or deuterons. These sources generally work in cw mode. A 2.45 GHz ECR test stand based on a pure volume H− ion production is currently under development. This negative ion source is working in pulsed mode, 1 ms at 10 Hz. The first H− ions have been observed at the beginning of 2002 with a poor efficiency. Only a few μA were produced. To avoid negative ions destruction by a nonabsorbed microwave close to the extraction aperture, a stainless steel grid was installed in the rectangular plasma chamber. As a result, the chamber is now effectively separated into two zones: the ECR plasma generator and the H− production zone. By plotting the extracted current versus the production zone length, the H− ion intensity reached more than 100 μA with the grid located 25 mm from the aperture. A voltage difference on the order of 10 V can be app...

Published

2004

14. Efficiency measurements for a low charge state ionic injection into an electron beam ion source

Author

P A. Leroy, Raphael Gobin, Francis Harrault, B. Visentin, and P. Van Duppen

Subjects

Nuclear and High Energy Physics, Argon, Ion beam, Chemistry, Analytical chemistry, chemistry.chemical_element, Ionic bonding, Nitrogen, Ion source, Ion, Ion beam deposition, Cathode ray, Atomic physics, Instrumentation

Abstract

We report injection efficiency measurements when an external primary low charge ion beam is injected into Dione EBIS. These measurements have been performed using nitrogen and argon ion beams. The total efficiencies reach 59 and 52% respectively. The partial efficiencies, related to the main ionic charge state, reaches 30% for N 7+ and 9.4% for Ar 14+ . These results correspond to an injection before the confinement period (fast injection mode). The other method (injection during the confinement time) has been also performed using nitrogen ions. The results are less spectacular: only a 0.4% total efficiency has been measured.

Published

1995

15. Installation and first operation of the International Fusion Materials Irradiation Facility injector at the Rokkasho site

Author

Benoit Bolzon, J.-M. Ayala, Yoshikazu Okumura, Nicolas Chauvin, Adelino Gomes, D. Bogard, Alvaro Marqueta, Francis Harrault, Matthieu Valette, Daniel Duglue, G. Bourdelle, Dominique Gex, Juan Knaster, Denis Loiseau, S. Ohira, Atsushi Kasugai, Philippe Cara, Arnaud Roger, Patrice Guiho, K. Shinto, Raphael Gobin, Yves Lussignol, Franck Senée, P. Girardot, Hiroki Takahashi, S. Chel, and Nicolas Misiara

Subjects

Physics, High intensity, Nuclear engineering, Beam commissioning, International Fusion Materials Irradiation Facility, Injector, 01 natural sciences, Linear particle accelerator, 010305 fluids & plasmas, law.invention, Chopper, Nuclear physics, Acceptance testing, law, 0103 physical sciences, 010306 general physics, Instrumentation, Beam (structure)

Abstract

The International Fusion Materials Irradiation Facility (IFMIF) linear IFMIF prototype accelerator injector dedicated to high intensity deuteron beam production has been designed, built, and tested at CEA/Saclay between 2008 and 2012. After the completion of the acceptance tests at Saclay, the injector has been fully sent to Japan. The re-assembly of the injector has been performed between March and May 2014. Then after the check-out phase, the production of the first proton beam occurred in November 2014. Hydrogen and deuteron beam commissioning is now in progress after having proceeded with the final tests on the entire injector equipment including high power diagnostics. This article reports the different phases of the injector installation pointing out the safety and security needs, as well as the first beam production results in Japan and chopper tests. Detailed operation and commissioning results (with H(+) and D(+) 100 keV beams) are reported in a second article.

Published

2016

16. Measurement of ion species in high current ECR H+/D+ ion source for IFMIF (International Fusion Materials Irradiation Facility)

Author

Franck Senée, Kotaro Kondo, Matthieu Valette, A. Ihara, J.-M. Ayala, Atsushi Kasugai, Yujiro Ikeda, T. Kitano, Alvaro Marqueta, Nicolas Chauvin, K. Shinto, Raphael Gobin, Benoit Bolzon, Ryo Ichimiya, Hiroki Takahashi, and Yoshikazu Okumura

Subjects

010302 applied physics, Materials science, Ion beam, Proton, Particle accelerator, International Fusion Materials Irradiation Facility, 01 natural sciences, Ion source, 010305 fluids & plasmas, law.invention, Ion, Deuterium, Physics::Plasma Physics, law, 0103 physical sciences, Physics::Accelerator Physics, Thermal emittance, Atomic physics, Instrumentation

Abstract

Ion species ratio of high current positive hydrogen/deuterium ion beams extracted from an electron-cyclotron-resonance ion source for International Fusion Materials Irradiation Facility accelerator was measured by the Doppler shift Balmer-α line spectroscopy. The proton (H(+)) ratio at the middle of the low energy beam transport reached 80% at the hydrogen ion beam extraction of 100 keV/160 mA and the deuteron (D(+)) ratio reached 75% at the deuterium ion beam extraction of 100 keV/113 mA. It is found that the H(+) ratio measured by the spectroscopy gives lower than that derived from the phase-space diagram measured by an Allison scanner type emittance monitor. The H(+)/D(+) ratio estimated by the emittance monitor was more than 90% at those extraction currents.

Published

2016

17. Transport of intense ion beams and space charge compensation issues in low energy beam lines (invited)

Author

R. Duperrier, Didier Uriot, Nicolas Chauvin, P. A. P. Nghiem, Raphael Gobin, and Olivier Delferrière

Subjects

Physics, Particle accelerator, Space charge, Ion source, Computational physics, law.invention, Compensation (engineering), Radio-frequency quadrupole, law, Physics::Accelerator Physics, Thermal emittance, Atomic physics, Beam emittance, Instrumentation, Beam (structure)

Abstract

Over the last few years, the interest of the international scientific community for high power accelerators in the megawatt range has been increasing. For such machines, the ion source has to deliver a beam intensity that ranges from several tens up to a hundred of mA. One of the major challenges is to extract and transport the beam while minimizing the emittance growth and optimizing its injection into the radio frequency quadrupole. Consequently, it is crucial to perform precise simulations and cautious design of the low energy beam transport (LEBT) line. In particular, the beam dynamics calculations have to take into account not only the space charge effects but also the space charge compensation of the beam induced by ionization of the residual gas. The physical phenomena occurring in a high intensity LEBT and their possible effects on the beam are presented, with a particular emphasis on space charge compensation. Then, beam transport issues in different kind of LEBTs are briefly reviewed. The SOLMAXP particle-in-cell code dedicated to the modeling of the transport of charge particles under a space charge compensation regime is described. Finally, beam dynamics simulations results obtained with SOLMAXP are presented in the case of international fusion materials irradiation facility injector.

Published

2012

18. First plasma analysis of the CEA/Saclay ECR hydrogen negative ion source

Author

Joseph D. Sherman, R. Ferdinand, Francis Harrault, P.-Y. Beauvais, K. Benmeziane, J.-M. Lagniel, Raphael Gobin, and Olivier Delferrière

Subjects

Dipole, Materials science, Proton, Physics::Plasma Physics, Electron, Plasma, Atomic physics, Instrumentation, Magnetic dipole, Ion source, Electron cyclotron resonance, Ion

Abstract

Reliable high intensity H− ion source development is now part of the CEA/Saclay work in the field of high intensity linear accelerators. A 2.45 GHz electron cyclotron resonance (ECR) H− ion source and test bench have been built. This new source has been designed taking into account our experience on the French high intensity ECR proton source. For H− ion production, the high-energy electrons created in the ECR zone are trapped by a dipole magnetic filter. A rectangular 210 mm long plasma chamber and an intermediate iron shield are used to minimize the magnetic field in the extraction region. A second magnetic dipole separates electrons and negative ions in a 10 kV extraction system. To reduce the electron/H− ratio, the plasma electrode is biased by a power supply. The first helium plasma allowed us to verify the satisfactory electron separator behavior. Pulsed hydrogen plasma is currently produced. The first plasma characterization is under progress as a function of ion source parameters by using Langmuir...

Published

2002

19. TRIPS: The high intensity proton source for the TRASCO project

Author

Santo Gammino, Raphael Gobin, Luigi Celona, R. Ferdinand, and G. Ciavola

Subjects

Root mean square, Physics, Nuclear transmutation, Proton, Nuclear engineering, Continuous wave, Radioactive waste, Thermal emittance, Instrumentation, Beam (structure), Linear particle accelerator

Abstract

The TRASCO project (trasmutazione scorie) is a R&D program whose goal is the design of an accelerator driving system for nuclear waste transmutation. The high current continuous wave proton linear accelerator will drive a subcritical system to transmutate nuclear wastes, while producing energy. The proton source TRIPS is a high intensity microwave source, which should be highly reliable and that should provide a minimum proton current of 50 mA with a r−r′ root mean square normalized emittance lower than 0.2 π mm mrad. A program of cooperation has been entered into with CEA-Saclay, where the IPHI project is in progress and the proton source SILHI has been designed and built using goals close to those of TRIPS. The construction of TRIPS is underway and the first beam is scheduled for the first half of 2000. The main features of this source and the results of the optics calculations are presented.

Published

2000

20. Time resolving diagnostic of the compensation process of pulsed ion beams at high-intensity light ion source

Author

Raphael Gobin, P. A. Leroy, P.-Y. Beauvais, A. Jakob, J. Pozimski, J. L. LeMaire, and H. Klein

Subjects

Ion beam deposition, Materials science, Ion beam, Plasma parameters, Charge coupled device camera, Atomic physics, Ion gun, Instrumentation, Ion source, Beam (structure), Ion

Abstract

Time-resolved measurements of the compensation process have been performed at the (high-intensity light ion source)-low-energy beam transport test stand (CEA-Saclay) using an 92 kV; 73 mA proton beam. A residual gas ion energy analyzer was used to measure the potential distribution as a function of time. To measure the radial density profile of the ion beam a charge coupled device camera has been used to perform time-resolved measurements and to estimate the rise time of compensation. Both measurements in combination allow an investigation of the space-charge compensation process due to the residual gas ionization and the experimental study of the rise of compensation. A numerical simulation of selfconsistent equilibrium states [J. Pozimski, Il Nuovo Cimento 106, A.N.11 (1993)] of the ion beam has been used to determine plasma parameters such as the density and the temperature of the electrons from the measured data. An interpretation of the acquired data and the achieved results is given.

Published

2000

21. Electron cyclotron resonance 140 mA D(+) beam extraction optimization for IFMIF EVEDA accelerator

Author

D. De Menezes, Olivier Tuske, O. Delferrière, Raphael Gobin, and Francis Harrault

Subjects

Nuclear physics, Materials science, law, International Fusion Materials Irradiation Facility, Neutron, Thermal emittance, Particle accelerator, Fusion power, Instrumentation, Ion source, Electron cyclotron resonance, Beam (structure), law.invention

Abstract

Based on the experience of the SILHI electron cyclotron resonance (ECR) ion source for the IPHI accelerator, which produces routinely 100-120 mA H(+) beam, the CEA-Saclay is in charge of the design and realization of the 140 mA cw deuteron source for the IFMIF project (International Fusion Materials Irradiation Facility). IFMIF is an accelerator-based neutron irradiation facility consisting of two accelerators of 125 mA D(+) beam at 40 MeV that hit in parallel a lithium target. IFMIF utilizes the deuteron-lithium (d-Li) neutron, producing a reaction to simulate the 14 MeV neutron environment in deuterium-tritium (D-T) fusion reactors. In the framework of the IFMIF EVEDA phase (Engineering Validation and Engineering Design Activities), we are studying a cw ECR ion source with a new extraction system to allow high current extraction while keeping a low divergence as well as a small emittance. Starting from SILHI five-electrode system with H(+) ions, the extracted beam characteristics as well as electric field conditions are compared with the cases of four- and three-electrode extraction systems. Experimental results made on the SILHI source with H(+) ions are briefly discussed. Extensive experimental results on the new source test bench BETSI are expected as soon as the design and fabrication of a dedicated extraction system with a new set of electrodes will be finished.

Published

2008

22. ECRIN and MultiCusp Sources at CEA Saclay

Author

Olivier Tuske, A. Madur, D. De Menezes, Y. Gauthier, G. Charruau, Raphael Gobin, Olivier Delferrière, and Francis Harrault

Subjects

Nuclear physics, Test bench, Chemistry, Magnet, Cyclotron resonance, Pulsed mode, Atomic physics, Electron cyclotron resonance, Ion source, Ion

Abstract

A 2.45 GHz electron cyclotron resonance test stand based on a pure volume H− negative ion production is presently running at CEA Saclay. This negative ion source (ECRIN) is working in pulsed mode, up to 10 ms at 10 Hz. Several modifications allowed increasing the extracted H− current from the source. Those results will be summed up in the first part. With the experience collected from this source, a second one using a multi‐cups magnetic structure is under development. Magnetic calculations and simulations showed that an octupolar configuration could allow improving the H− ion production. Those simulations will be discussed and the new set up will also be presented. The source is now being assembled on a new test bench, called BETSI, for light ion source development based on permanent magnet structure.

Published

2007

23. Improvement of Reliability of the Trasco Intense Proton Source Trips at INFN-LNS

Author

L. Andò, G. Ciavola, S. Passarello, M. Presti, Joseph D. Sherman, R. Ferdinand, S. Gammino, X.-Z.-H. Zhang, Raphael Gobin, L. Celona, F. Chines, M. Winkler, and A. Galatà

Subjects

Engineering, business.industry, Nuclear engineering, Electrical engineering, Transfer line, Magnetic field, Proton (rocket family), Neodymium magnet, Reliability (semiconductor), Magnet, Physics::Accelerator Physics, TRIPS architecture, business, Beam (structure)

Abstract

Over the past two years, INFN-LNS has undertaken to improve the source reliability for high-power proton accelerators. A full set of magnetic field measurements has been carried out to define a different design of the TRIPS magnetic system, based on permanent magnets, in order to increase the reliability of the source devoted to the ADS. The OPERA-3D package was used to design the new magnetic system as a combination of three rings of NdFeB magnets and soft iron in between. The description of the magnetic measurements and the comparison with the simulations are presented, along with the design of a new version of the source, called PM-TRIPS. Finally the new low-energy beam transfer line (LEBT) will be described, with particular regard to the improvement of accelerator availability, which can be obtained with the installation of two PM-TRIPS sources or more on a switching magnet.

Published

2006

24. 2D PIC-MCC Code for Electron-Hydrogen Gas Interaction Study in H− Ion Sources

Author

Joseph D. Sherman, Raphael Gobin, R. Ferdinand, K. Benmeziane, and Gerard Gousset

Subjects

Volume (thermodynamics), Hydrogen, chemistry, law, chemistry.chemical_element, Charge density, Particle accelerator, Electron, Atomic physics, Space charge, Ion source, law.invention, Ion

Abstract

In order to make a reliable H− ion source, a hybrid PIC 2D MCC 3D fluid code has been developed. The aim of the code is to study the effect of electron injection into a cylindrical gas chamber. This new version takes into account the 2D space charge distribution. Thus, it is possible to calculate the H− ion distribution everywhere in the plasma chamber. Many results have been brought as well as the best injected energy and the electron penetration length efficiency. Moreover, the calculations explain why it is more problematic to get an efficient volume production at high pressure (100 mTorr) than at low pressure (6 mTorr). The temporal H− production evolution is finally discussed.

Published

2005

25. Status of the Negative Hydrogen Ion Test Stand at CEA Saclay

Author

O. Delferrière, Raphael Gobin, A. Girard, K. Benmeziane, R. Ferdinand, and Francis Harrault

Subjects

Ion beam, Chemistry, Analytical chemistry, Plasma, Electron cyclotron resonance, Ion, symbols.namesake, symbols, media_common.cataloged_instance, Langmuir probe, Plasma diagnostics, Atomic physics, European union, Electric current, media_common

Abstract

At CEA‐Saclay, in 2003, the new 2.45 GHz ECR source, based on pure volume H− ion production, showed a dramatic increase of the H− extracted ion beam. In fact, since the rectangular plasma chamber is separated in two different parts by a stainless steel grid, the extracted H− current rose from few μA to 1.5 mA. Of course the grid position and its potential with respect to the plasma chamber were optimised. Ceramic plates allow increasing the electron density and lead to an improvement of the negative ion production. Plasma characterization by using Langmuir probes and positive charge analysis are also presented. The last results are reported and discussed. This work is part of the High Performance Negative Ion Sources (HPNIS) program and supported by the European Union under contract HPRI‐CT‐2001‐50021.

Published

2005

26. First results on the warm EBIS source at Saclay

Author

J. P. Briand, G. Congretel, Raphael Gobin, B. Visentin, P. Leaux, P. Gros, S. Thuriez, Olivier Delferrière, J. Faure, A. Courtois, P. A. Leroy, Francis Harrault, and G. Giardino

Subjects

Materials science, Cathode ray, Solenoid, High current, Atomic physics, Instrumentation, Current density, Ion, Magnetic field

Abstract

A large high current EBIS source, working at room temperature, and using a noncryogenic solenoid, has been completed in Saclay. This source, whose current density is lower (≊100 A cm−2) than the cryogenic EBIS, has been designed to be used at very low pressures with turbo and Ti sublimator pumping. An ultimate vacuum of 8×10−12 mbar has been reached and may be obtained in a few days after opening. This ultrahigh vacuum allows very long confinement times. The electron beam has been injected and large amounts of Ar16+ and Ar17+ ions have been obtained in July. These preliminary results are in good agreement with theoretical simulations. More details about the special dynamics of the warm EBIS are presented.

Published

1996

27. First results of a high‐current electron cyclotron resonance proton source

Author

M. Delaunay, P. A. Leroy, Raphael Gobin, G. Melin, A. Farchi, J.-M. Lagniel, Olivier Delferrière, and J. Faure

Subjects

Waveguide (electromagnetism), Materials science, Proton, Plasma, Electron, Atomic physics, Instrumentation, Electron cyclotron resonance, Fourier transform ion cyclotron resonance, Ion cyclotron resonance, Ion source

Abstract

A 2.45 GHz electron cyclotron resonance (ECR) ion source for producing a 100 mA H+ beam is under study. The microwave power is coupled through a quartz window and a water‐cooled 90° waveguide bend in order to avoid the heating of the electrons backstreaming from the source. The ECR condition is obtained with dc magnetic coils. Preliminary results reported here show that a beam current density of 75 mA/cm2 can be extracted at 10 kV from a 3‐mm‐diam aperture, with 1.2 kW of microwave power at 1×10−3 mbar of hydrogen pressure. The proton fraction is 75% with an alumina‐coated plasma electrode and 85% with a nitride coating.

Published

1996

28. A hollow cathode ion source as an electron‐beam ion source injector for metallic elements

Author

B. Visentin, Raphael Gobin, Francis Harrault, and P. A. Leroy

Subjects

Glow discharge, Materials science, Ion beam deposition, Ion beam, Cathode ray, Atomic physics, Beam emittance, Ion gun, Instrumentation, Ion source, Ion

Abstract

A hollow cathode ion source (HCIS) has been developed in our Laboratory to produce, by cathodic sputtering in a glow discharge, a one charge metallic ion beam. This source is used as an injector for the electron‐beam ion source (EBIS) Dione that produce, after ion stripping, a highly charged heavy‐ion beam for acceleration in Mimas–Saturne synchrotrons. Due to the good pulse‐to‐pulse repeatability of the HCIS, the very long lifetime of the cathode (several months), as well as the very good value of the normalized emittance (enorm=4×10−9 π mrad), this source appears as an ideal EBIS injector for metallic and gaseous elements. In this paper we report the description of the HCIS and the experimental results achieved, after injection in the EBIS, by the production of heavy‐ion beams like Fe20+, Au50+, and U55+ (from 4×107 to 9×106 ions/cycle).

Published

1994

29. Effective shielding to measure beam current from an ion source

Author

J. Marroncle, Raphael Gobin, Franck Senée, Olivier Delferrière, Olivier Tuske, C.S.Simon, H. Bayle, and Francis Harrault

Subjects

Physics, Physics::Instrumentation and Detectors, Nuclear engineering, Shields, Particle accelerator, Solenoid, Current transformer, Linear particle accelerator, law.invention, Nuclear physics, law, Shielded cable, Electromagnetic shielding, Physics::Accelerator Physics, Transformer, Instrumentation

Abstract

To avoid saturation, beam current transformers must be shielded from solenoid, quad, and RFQ high stray fields. Good understanding of field distribution, shielding materials, and techniques is required. Space availability imposes compact shields along the beam pipe. This paper describes compact effective concatenated magnetic shields for IFMIF-EVEDA LIPAc LEBT and MEBT and for FAIR Proton Linac injector. They protect the ACCT Current Transformers beyond 37 mT radial external fields. Measurements made at Saclay on the SILHI source are presented.

Published

2014

30. Advanced light ion source extraction system for a new electron cyclotron resonance ion source geometry at Saclay

Author

Olivier Tuske, S. Nyckees, Raphael Gobin, Francis Harrault, Y. Sauce, and O. Delferrière

Subjects

Physics, Ion beam, Cyclotron resonance, Particle accelerator, Solenoid, Geometry, Ion source, law.invention, law, Physics::Accelerator Physics, Thermal emittance, Laser beam quality, Instrumentation, Beam (structure)

Abstract

One of the main goal of intense light ion injector projects such as IPHI, IFMIF, or SPIRAL2, is to produce high current beams while keeping transverse emittance as low as possible. To prevent emittance growth induced in a dual solenoid low energy transfer line, its length has to be minimized. This can be performed with the advanced light ion source extraction system concept that we are developing: a new ECR 2.45 GHz type ion source based on the use of an additional low energy beam transport (LEBT) short length solenoid close to the extraction aperture to create the resonance in the plasma chamber. The geometry of the source has been considerably modified to allow easy maintenance of each component and to save space in front of the extraction. The source aims to be very flexible and to be able to extract high current ion beams at energy up to 100 kV. A specific experimental setup for this source is under installation on the BETSI test bench, to compare its performances with sources developed up to now in the laboratory, such as SILHI, IFMIF, or SPIRAL2 ECR sources. This original extraction source concept is presented, as well as electromagnetic simulations with OPERA-2D code. Ion beam extraction in space charge compensation regime with AXCEL, and beam dynamics simulation with SOLMAXP codes show the beam quality improvement at the end of the LEBT.

Published

2012

31. Preliminary results of the International Fusion Materials Irradiation Facility deuteron injector

Author

Olivier Delferrière, Denis Loiseau, D. Bogard, Francis Harrault, J.L.Jannin, P. Guiho, Franck Senée, Y. Sauce, T. Vacher, G. Adroit, G. Bourdelle, Arnaud Roger, Nicolas Chauvin, Y. Gauthier, P. Girardot, Raphael Gobin, and P. Mattei

Subjects

Materials science, Physics::Instrumentation and Detectors, International Fusion Materials Irradiation Facility, Particle accelerator, Electron cyclotron resonance, Ion source, law.invention, Nuclear physics, Radio-frequency quadrupole, Beamline, law, Physics::Accelerator Physics, Instrumentation, Beam (structure), Beam divergence

Abstract

In the framework of the IFMIF-EVEDA project (International Fusion Materials Irradiation Facility-Engineering Validation and Engineering Design Activities), CEA∕IRFU is in charge of the design, construction, and characterization of the 140 mA continuous deuteron injector, including the source and the low energy beam line. The electron cyclotron resonance ion source which operates at 2.45 GHz is associated with a 4-electrode extraction system in order to minimize beam divergence at the source exit. Krypton gas injection is foreseen in the 2-solenoid low energy beam line. Such Kr injection will allow reaching a high level of space charge compensation in order to improve the beam matching at the radio frequency quadrupole (RFQ) entrance. The injector construction is now completed on the Saclay site and the first plasma and beam production has been produced in May 2011. This installation will be tested with proton and deuteron beams either in pulsed or continuous mode at Saclay before shipping to Japan. In this paper, after a brief description of the installation, the preliminary results obtained with hydrogen gas injection into the plasma chamber will be reported.

Published

2012

32. General design of the International Fusion Materials Irradiation Facility deuteron injector: Source and beam line

Author

J.L.Jannin, J.-Y. Rousse, S. Langlois, Franck Senée, V. Blideanu, D. Bogard, Denis Loiseau, P. Girardot, Nicolas Chauvin, Olivier Delferrière, B. Pottin, G. Bourdelle, and Raphael Gobin

Subjects

Physics, Nuclear engineering, International Fusion Materials Irradiation Facility, Solenoid, Injector, Electron cyclotron resonance, law.invention, Nuclear physics, Radio-frequency quadrupole, Beamline, law, Neutron source, Instrumentation, Beam (structure)

Abstract

In the framework of the International Fusion Materials Irradiation Facility-Engineering Validation and Engineering Design Activities (IFMIF-EVEDA) project, CEA/IRFU is in charge of the design and realization of the 140 mA cw deuteron Injector. The electron cyclotron resonance ion source operates at 2.45 GHz and a 4 electrode extraction system has been chosen. A 2 solenoid beam line, together with a high space charge compensation have been optimized for a proper beam injection in the 175 MHz radio frequency quadrupole. The injector will be tested with proton and deuteron beam production either in pulsed mode or in cw mode on the CEA-Saclay site before to be shipped to Japan. Special attention was paid to neutron emission due to (d,D) reaction. In this paper, the general IFMIF Injector design is reported, pointing out beam dynamics, radioprotection, diagnostics, and mechanical aspects.

Published

2010

33. BETSI, a new test bench for ion sources optimization at CEA SACLAY

Author

Raphael Gobin, O. Tuske, Y. Gauthier, D. De Menezes, G. Adroit, Francis Harrault, and Olivier Delferrière

Subjects

Nuclear physics, Physics, Test bench, Nuclear engineering, Thermal emittance, Plasma diagnostics, Laser beam quality, Radio frequency, Instrumentation, Ion source, Beam (structure), Electron cyclotron resonance

Abstract

In the framework of several International HPPA projects (such as IFMIF, IPHI, and Spiral2) the CEA handles the design and the developments of several electron cyclotron resonance (ECR) ion sources. For the IFMIF EVEDA demonstrator, a 140 mA cw extracted deuteron beam will be required for high yield of neutron production. For radioactive ion production in the Spiral2 project, several milliamperes of deuterons will be delivered with a permanent magnet source. The optimization of the beam quality at the entrance of the radio frequency quadropole (RFQ) accelerator system triggered the need of a new test bench for ion source optimization and beam qualification. The BETSI ion source test bench will operate up to 50 kV and ignite cw or pulsed hydrogen plasma with a 2.45 GHz magnetron. Great care has already been taken to design electrostatic optics of the extraction system to minimize the emittance growth. Plasma diagnostics will be inserted in the source chamber and several beam diagnostics (emittance and current measurements, beam species analysis) will also be implemented on the low energy beam line transport (LEBT). These diagnostics allow the simultaneous analysis of the beam quality with the plasma parameters of the source. Regional funding request will also be needed to improve the LEBT for space charge compensation measurements. The design of the present and upgraded test bench will be reported as well as the first extracted beam analysis.

Published

2008

34. A 140 mA cw deuteron electron cyclotron resonance source for the IFMIF-EVEDA project

Author

Raphael Gobin, Olivier Delferrière, Y. Gauthier, Olivier Tuske, G. Adroit, P.-Y. Beauvais, Francis Harrault, and D. De Menezes

Subjects

Physics, Nuclear physics, Low energy, Deuterium, Beamline, High intensity, Pulsed mode, Neutron, Instrumentation, Beam (structure), Electron cyclotron resonance

Abstract

In the framework of the IFMIF-EVEDA phase (International Fusion Materials Irradiation Facility-Engineering Validation and Engineering Design Activities), the CEA-Saclay is in charged of the design and realization of the 140 mA cw deuteron source. The IFMIF EVEDA demonstrator will be installed in Japan in the next six years and will have to accelerate the deuteron beam up to 9 MeV. CEA will build the source and the low energy beam line (LEBT) and will test the cw high intensity deuteron production at Saclay. The SILHI source is an electron cyclotron resonance (ECR) source, operating at 2.45 GHz. In 2001, it produced more than 130 mA of deuteron beam in pulsed mode to minimize neutron production. Such a result pushes to develop a new ECR source based on the SILHI design and equipped with a specific extraction system. Several options of the accelerator column will be implemented in order to improve the reliability and the efficiency of the source. The IFMIF source and LEBT design will be reported.

Published

2008

35. Development of a permanent magnet light ion source at CEA/Saclay

Author

G. Charruau, Raphael Gobin, Olivier Delferrière, D. De Menezes, Y. Gauthier, Francis Harrault, J. Y. Pacquet, P. Leherissier, Département d'Astrophysique, de physique des Particules, de physique Nucléaire et de l'Instrumentation Associée (DAPNIA), Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Grand Accélérateur National d'Ions Lourds (GANIL), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), and SPIRAL2

Subjects

deuteron sources, linear accelerators, Physics, Aperture, ion accelerators, 29.25.Ni, 29.27.Fh, 29.17.+w, 29.20.Hm, Cyclotron, permanent magnets, Cyclotron resonance, Particle accelerator, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Ion source, Linear particle accelerator, law.invention, Nuclear physics, law, Magnet, Physics::Accelerator Physics, particle beam diagnostics, cyclotron resonance, proton sources, Nuclear Experiment, cyclotrons, Instrumentation, Beam (structure)

Abstract

International audience; In France, the Spiral 2 project dedicated to radioactive beam production is based on a 40 MeV continuous wave (cw) deuteron Linac. This installation will allow extending the variety of accelerated particles to very heavy elements. Such beams will open research domains for the GANIL facility. To inject the requested 5 mA deuteron beam into the Spiral 2 Linac, the performance of the high intensity light ion source (SILHI) allowed us to propose such an electron cyclotron resonance source. SILHI, developed at CEA/Saclay, regularly produces high intensity (over 100 mA) proton or deuteron beams through a $\Phi$ 9 mm aperture. So for this project, the main modifications of the source design concern the permanent magnets which provide the axial magnetic configuration and the $\Phi$ 3 mm aperture. The source produced its first beam (proton) in 2004. This article will report the beam characterization while the source produced $D^+$ beam with intensity as high as 7.0 mA. Recently, this permanent magnet source has been equipped with the $\Phi$ 9 mm plasma electrode. So high intensity proton beams reaching more than 100 mA are now extracted from this source.

Published

2006

36. Results of the CEA/Saclay H electron cyclotron resonance ion source, ECRIN

Author

Olivier Delferrière, Olivier Tuske, T. Steiner, Francis Harrault, and Raphael Gobin

Subjects

Materials science, Hydrogen, chemistry.chemical_element, Particle accelerator, Plasma, Electron cyclotron resonance, Ion source, law.invention, Ion, chemistry, law, Excited state, Atomic physics, Instrumentation, Beam (structure)

Abstract

A 2.45GHz electron cyclotron resonance test stand based on a pure volume H− (negative) ion production is actually under development at CEA Saclay. The negative ion source is working in a pulsed mode, 2ms at 5–10Hz. The first H− ions have been observed at the beginning of 2002 with a poor efficiency: only a few microamperes were produced. Several changes inside the plasma chamber have increased the production rate of negative ions up to several milliamperes. A biased grid separates the plasma chamber into two regions. In the first part, we produce excited H2 molecules that are necessary for producing in the second zone H− ions by a dissociative attachment process located near the extraction zone. Qualitative and quantitative beam diagnostics allow measuring several beam parameters and analyzing the effect of gas mixing or materials on the H− production rate.

Published

2006

37. DIONÉ status report

Author

P. Zupranski, B. Visentin, P. A. Leroy, A. Courtois, Raphael Gobin, and J. Faure

Subjects

Materials science, Ion beam, Status report, Ion gun, Synchrotron, Ion source, law.invention, Ion, Nuclear physics, Ion beam deposition, law, Atomic physics, Instrumentation, Evaporative cooler

Abstract

The SATURNE synchrotron facility is equipped with an EBIS source for heavy ion nuclear‐physics experiments. SATURNE is accelerating either conventional heavy ions as Kr30+ or polarized 6Li3+ produced in two external ion sources, injected and stripped inside DIONE. In this paper, the DIONE last performances will be given and recent developments as well: evaporative cooling experiments and the main options for a new EBIS project: RHEA.

Published

1992

38. A new operating regime for cryebis

Author

B. Feinberg, Raphael Gobin, A. Courtois, and J. Faure

Subjects

business.industry, Chemistry, General Engineering, Cathode ray, Optoelectronics, business, Space charge, Pulse (physics)

Abstract

CRYEBIS has been operating at more than ten times the space charge well capacity of the electron beam. Reliable production of >10 9 charges per pulse of N 7+ and Ne 10+ has been achieved.

Published

1984

39. External ion injection into CRYEBIS

Author

Raphael Gobin, J. Faure, A. Courtois, and B. Feinberg

Subjects

Chemistry, Shot (pellet), Ion injection, General Engineering, Charge (physics), Atomic physics, Solid material, External source, Ion source, Ion

Abstract

CRYEBIS, a source of high charge state heavy ions, has been successfully operated with the use of an external low charge state ion source. Injection of ions in this manner makes CRYEBIS operation independent of the working material. The use of an external source opens up the possibilities of producing high charge states of solid materials, as well as the possibility of changing materials on a shot to shot basis.

Published

1984

40. Improvement of beam emittance of the CEA high intensity proton source SILHI

Author

G. Ciavola, P.-Y. Beauvais, Luigi Celona, Raphael Gobin, Santo Gammino, R. Ferdinand, and P. A. Leroy

Subjects

Nuclear physics, Physics, Beamline, Proton, High intensity, Thermal emittance, Beam emittance, Instrumentation, Beam (structure)

Abstract

The emittance of the intense proton beam extracted by the source SILHI at Commisariat a l’Energie Atomique (CEA)-Saclay is a key parameter for the design of the IPHI Project RFQ. This parameter has a relevant role even for the design of an intense proton source for the TRASCO project of Istituto Nazionale di Fisica Nucleare (INFN). The tests performed in the framework of CEA-INFN collaboration have been mainly devoted to a 75 mA beam emittance investigation injecting different gases in the beam line. The results show that the rms normalized emittance decreases up to a factor 3 while the beam losses induced by recombination are contained within 5%. Normalized emittance in r-r′ plane of about 0.1 π min mrad have been obtained using Ar and Kr.

41. The accomplishment of the Engineering Design Activities of IFMIF/EVEDA: The European - Japanese project towards a Li(d,xn) fusion relevant neutron source

Author

Takehiko Yokomine, Nicolas Chauvin, Javier Abal, A. Delgado, M. Yamamoto, P. Diaz-Arocas, H. Matsumoto, M. Perez, Giuseppe Pruneri, F.S. Nitti, V. Massaut, T. Kubo, David Rapisarda, V. Queral, Angela Garcia, S. Ohira, Dolores Pérez, M. Frisoni, N. Casal, M. Weber, Didier Uriot, Martin Mittwollen, Fernando Mota, Mizuho Ida, Pierre-Yves Beauvais, D. Bernardi, Masayoshi Sugimoto, Gioacchino Miccichè, J. M. Carmona, R. Heidinger, K. Tian, Kazuhiro Watanabe, A. Mas, F. Arranz, Philippe Gouat, J. C. Mora, T. Kikuchi, P. A. P. Nghiem, Angel Ibarra, Francisco Ogando, F. Groeschel, O. Delferriere, Frederik Arbeiter, Enric Bargalló, Juan Knaster, Willem Leysen, Eiichi Wakai, J. Theile, Michel Soldaini, Y. Le Tonqueze, Ali Abou-Sena, Kotaro Kondo, M. Shingala, R. Román, Michele Comunian, P. Garin, K. Nishiyama, Tonio Pinna, F. Orsini, Ivan Podadera, Jose Manuel Arroyo, H. Umeno, Concepcion Oliver, A. Pisent, Maria Teresa Porfiri, Ulrich Fischer, Raphael Gobin, Universitat Politècnica de Catalunya. NERG - Grup de Recerca d'Enginyeria Nuclear, Porfiri, M., Pinna, T., Micciche, G., Frisoni, M., and Bernardi, D.

Subjects

Accelerator Physics (physics.acc-ph), Nuclear and High Energy Physics, Computer science, Energies [Àrees temàtiques de la UPC], Nuclear engineering, FOS: Physical sciences, International Fusion Materials Irradiation Facility, Material, Reliability (semiconductor), IFMIF, Fusió nuclear, Fusion, Materials, Flexibility (engineering), Física [Àrees temàtiques de la UPC], fusión nuclear, Schedule (project management), Neutron source, Condensed Matter Physics, Cost reduction, Electromagnetic shielding, Nuclear fusion, Physics - Accelerator Physics, Engineering design process

Abstract

The International Fusion Materials Irradiation Facility (IFMIF), presently in its Engineering Validation and Engineering Design Activities (EVEDA) phase under the frame of the Broader Approach Agreement between Europe and Japan, accomplished in summer 2013, on schedule, its EDA phase with the release of the engineering design report of the IFMIF plant, which is here described. Many improvements of the design from former phases are implemented, particularly a reduction of beam losses and operational costs thanks to the superconducting accelerator concept, the re-location of the quench tank outside the test cell (TC) with a reduction of tritium inventory and a simplification on its replacement in case of failure, the separation of the irradiation modules from the shielding block gaining irradiation flexibility and enhancement of the remote handling equipment reliability and cost reduction, and the water cooling of the liner and biological shielding of the TC, enhancing the efficiency and economy of the related sub-systems. In addition, the maintenance strategy has been modified to allow a shorter yearly stop of the irradiation operations and a more careful management of the irradiated samples. The design of the IFMIF plant is intimately linked with the EVA phase carried out since the entry into force of IFMIF/EVEDA in June 2007. These last activities and their on-going accomplishment have been thoroughly described elsewhere (Knaster J et al [19]), which, combined with the present paper, allows a clear understanding of the maturity of the European-Japanese international efforts. This released IFMIF Intermediate Engineering Design Report (IIEDR), which could be complemented if required concurrently with the outcome of the on-going EVA, will allow decision making on its construction and/or serve as the basis for the definition of the next step, aligned with the evolving needs of our fusion community. © 2015 IAEA, Vienna.

42. Emittance improvement of the electron cyclotron resonance high intensity light ion source proton beam by gas injection in the low energy beam transport

Author

B. Pottin, Luigi Celona, P. A. Leroy, Joseph D. Sherman, P.-Y. Beauvais, R. Ferdinand, J.-M. Lagniel, Raphael Gobin, Santo Gammino, and G. Ciavola

Subjects

Materials science, Proton, Buffer gas, Physics::Accelerator Physics, Solenoid, Thermal emittance, Atomic physics, Instrumentation, Space charge, Ion source, Beam (structure), Electron cyclotron resonance

Abstract

SILHI is the ECR high intensity light ion source studied in France at C.E.A. Saclay. This is the source for the injector of the high intensity proton injector prototype developed by a CNRS-IN2P3 collaboration. 80 mA at 95 keV beams with a rms normalized r–r′ emittance lower than 0.3 π mm mrad and a proton fraction better than 85% are currently produced. Recently, it has been found that the injection in the low energy beam transport of a buffer gas had a strong effect on the emittance measured 1 m downstream of the focusing solenoid. By adding several gases (H2, N2, Ar, Kr), improvements as great as a factor of 3 have been observed. The emittance has been measured by means of an r–r′ emittance measurement unit equipped with a sampling hole and a wire profile monitor, both moving across the beam. Simultaneously, the space charge compensation factor is measured using a four-grid analyzer unit. In this article all results of these experiments are presented and discussed. A first explanation of the emittance r...