Your search keyword '"J.-L. Jannin"' showing total 4 results

1. Progress in Design and Construction of the ${\hbox {R}}^{3}{\hbox {B}}$-GLAD Large Acceptance Superconducting Dipole Spectrometer for GSI-FAIR

Author

P. Fazilleau, Chhon Pes, C. Berriaud, D. Loiseau, Hubert Neyrial, D. Eppelle, P Contrepois, J.P. Lottin, J.-E. Ducret, M. Massinger, G. Disset, B. Gastineau, P Charon, J.-L Jannin, Z. Sun, Patrick Graffin, Bertrand Baudouy, Y. Queinec, A. Donati, and C. Mayri

Subjects

Physics, Cryostat, Rutherford cable, Electromagnet, Mechanical engineering, Superconducting magnet, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, law.invention, Nuclear magnetic resonance, law, Electrical equipment, Magnet, Electromagnetic shielding, Shielded cable, Electrical and Electronic Engineering

Abstract

The R3B-Glad superconducting Magnet is a large acceptance dipole, dedicated to the analysis of Reactions with Relativistic Radioactive ions Beams. It takes part in the FAIR Project at GSI. As the superconducting NbTi Rutherford cable was under production, detailed studies of the mechanical structure (with both simulation and experiment on a half-scale mock-up) led to revise the magnet design and to abandon the grading of the coils in three stages. Due to the large magnetic forces (up to 400 tons/m), the maximum shear stress level of 20 MPa was impossible to meet in the coils. The main reasons consist in the orthotropic thermo-mechanical behavior of the coils together with the large differential thermal shrinkage between the Cu stabilized coils and their Al alloy casings. Indeed after several studies of different mechanical designs, we decided to simplify the magnet in order to cope with these difficulties. One innovative point is that the coils are not blocked at room temperature, but only at 4.5 K. This paper presents the magnetic calculations of this active shielded magnet, and shows how the new design features meet the specifications. Currently, the 22 tons magnet cold mass, i.e. the 6 coils and their integration in the casings, is ordered and under construction. Meanwhile, the design of the magnet cryostat has evolved into a shape of elliptical cylinder with a lateral satellite. The total weight is expected to be around 50 tons.

Published

2010

2. High intensity ECR ion source (H+, D+, H−) developments at CEA/Saclay

Author

R. Gobin, P.-Y. Beauvais, D. Bogard, G. Charruau, O. Delferrière, D. De Menezes, A. France, R. Ferdinand, Y. Gauthier, F. Harrault, J.-L. Jannin, J.-M. Lagniel, P.-A. Leroy, P. Mattéi, J. Sherman, A. Sinanna, P. Ausset, S. Bousson, and B. Pottin

Subjects

Nuclear physics, Materials science, Nuclear transmutation, Proton, law, Radioactive waste, Injector, Instrumentation, Electromagnetic interference, Beam (structure), Ion source, Ion, law.invention

Abstract

Source of light ions with high intensities The (SILHI) source has been producing proton beams since 1996. The first aim is to produce up to 100 mA cw beams at 95 keV for the injector of protons for high intensity demonstrator. This prototype is developed by a CEA/DSM–CNRS/IN2P3 collaboration for applications such as accelerator driven systems for nuclear waste transmutation, production of radioactive ion beams, or secondary particles. To measure installation reliability, continuous 5 day long runs have been performed. In October 1999, a 99.96% availability was achieved with a single short beam off and a 103 H uninterrupted beam. A new extraction system leads to lower beam losses and higher LEBT transparency. SILHI now produces a 95 keV–130 mA total beam with a proton fraction higher than 80%. Up to a 157 mA (247 mA/cm2) total cw beam has been extracted. The new EPICS control system, electromagnetic interference hardened devices and automatic control procedures now allow us to do longer runs. To analyze th...

Published

2002

3. Assessing Genomic Selection Prediction Accuracy in a Dynamic Barley Breeding Population

Author

A. H. Sallam, J. B. Endelman, J.-L. Jannink, and K. P. Smith

Subjects

Plant culture, SB1-1110, Genetics, QH426-470

Abstract

Prediction accuracy of genomic selection (GS) has been previously evaluated through simulation and cross-validation; however, validation based on progeny performance in a plant breeding program has not been investigated thoroughly. We evaluated several prediction models in a dynamic barley breeding population comprised of 647 six-row lines using four traits differing in genetic architecture and 1536 single nucleotide polymorphism (SNP) markers. The breeding lines were divided into six sets designated as one parent set and five consecutive progeny sets comprised of representative samples of breeding lines over a 5-yr period. We used these data sets to investigate the effect of model and training population composition on prediction accuracy over time. We found little difference in prediction accuracy among the models confirming prior studies that found the simplest model, random regression best linear unbiased prediction (RR-BLUP), to be accurate across a range of situations. In general, we found that using the parent set was sufficient to predict progeny sets with little to no gain in accuracy from generating larger training populations by combining the parent set with subsequent progeny sets. The prediction accuracy ranged from 0.03 to 0.99 across the four traits and five progeny sets. We explored characteristics of the training and validation populations (marker allele frequency, population structure, and linkage disequilibrium, LD) as well as characteristics of the trait (genetic architecture and heritability, ). Fixation of markers associated with a trait over time was most clearly associated with reduced prediction accuracy for the mycotoxin trait DON. Higher trait in the training population and simpler trait architecture were associated with greater prediction accuracy.

Published

2015

4. Status and new developments of the high intensity electron cyclotron resonance source light ion continuous wave, and pulsed mode (invited)

Author

J.-M. Lagniel, P.-Y. Beauvais, D. Bogard, G. Bourdelle, G. Charruau, O. Delferrière, D. De Menezes, A. France, R. Ferdinand, Y. Gauthier, R. Gobin, F. Harrault, J.-L. Jannin, P.-A. Leroy, I. Yao, P. Ausset, B. Pottin, N. Rouvière, L. Celona, and S. Gammino

Subjects

Nuclear physics, Materials science, Proton, Radio-frequency quadrupole, Continuous wave, Spallation, Atomic physics, Instrumentation, Electron cyclotron resonance, Linear particle accelerator, Ion source, Ion

Abstract

The high intensity light ion source (SILHI) is the electron cyclotron resonance (ECR) source constructed and tested at CEA-Saclay. The first aim is to produce up to 100 mA cw proton beams at 95 keV for the proton injection high intensity (IPHI) beams [5 MeV radio frequency quadrupole (RFQ) and 10 MeV drift tube linac (DTL)]. This prototype is developed by a CEA–CNRS-IN2P3 collaboration for applications such as accelerator driven systems for nuclear waste transmutation, production of radioactive ion beams or secondary particles. SILHI is also used to study the production of deuteron and H− beams for the International Fusion Material Irradiation Facility and European spallation source projects, respectively. The present status of SILHI and the experiments planned for the near future in both cw and pulsed modes are presented in this article. 80 mA cw proton beams are now currently produced at 95 keV with a high availability (∼1 spark/day). The proton fraction is around 90% and the typical r–r′ rms normalized...