Your search keyword '"Doré D."' showing total 15 results

1. Performance validation of the first arm of FALSTAFF: 252Cf and 235U fission fragment characterisation.

Author

Doré, D., Berthoumieux, E., Deshayes, Q., Thulliez, L., Legou, P., Combet, M., Kebbiri, M., Marcel, A., Mols, J-Ph., Frégeau, M.O., Herlant, S., Ledoux, X., Pancin, J., Oberstedt, S., Serot, O., and Chebboubi, A.

Subjects

*CALIFORNIUM, *URANIUM isotopes, *NUCLEAR fission, *NUCLEAR reactors, *NUCLEAR physics experiments

Abstract

The renewed interest for the study of nuclear fission is mainly motivated by the development of GEN-IV reactor concepts, mostly foreseen to operate in the fast neutron energy domain. To support this development, new high-quality nuclear data are needed. In this context, a new experimental setup, the FALSTAFF spectrometer, dedicated to the study of nuclear fission is under development. Employing the double-velocity (2V) and energy-velocity (EV) methods, the fission fragment mass before and after neutron evaporation will be deduced and the correlation between prompt neutron multiplicity and fragment mass will be determined. The first arm of the spectrometer is achieved. It is composed of two SED-MWPC detectors (a combination of a foil to produce secondary electrons and a Multi-Wire Proportional Chamber to detect them) and an axial ionization chamber. The SED-MWPC give access to the velocity (V) via time-of-flight and position measurements. The ionization chamber measures the fragment kinetic energy (E) and the energy loss profile. Preliminary results for spontaneous fission of 252Cf and from the thermal-neutron induced fission experiment on 235U, performed at the Orphée reactor (CEA-Saclay, France), are presented. [ABSTRACT FROM AUTHOR]

Published

2019

2. Recent developments of the FALSTAFF experimental setup.

Author

Köster, U., Chietera, A., Thulliez, L., Berthoumieux, E., Doré, D., Letourneau, A., Legou, P., Kebbiri, M., Piret, Y., Mols, J.P., Combet, M., Riallot, M., Marcel, A., Pancin, J., Frégeau, M. O., Ledoux, X., Lecolley, F. R., Perronnel, J., and Goupillere, D.

Subjects

NUCLEAR reactors, NUCLEAR fission, ACTINIDE elements, NEUTRON multiplicity, NUCLEAR fragmentation

Abstract

The study of nuclear fission is encountering renewed interest with the development of GEN-IV reactor concepts, mostly working in the neutron fast energy domain. To support the fast reactor technologies, new high quality nuclear data are needed. New facilities are being constructed to produce high intensity neutron beams from hundreds of keV to few tens of MeV (Licorne, NFS, nELBE,...). They will open new opportunities to provide nuclear data. In this framework the development of an experimental setup called FALSTAFF for a characterisation of actinide fission fragments has been undertaken. Fission fragment yields and associated neutron multiplicities will be measured as a function of the neutron energy. Based on time-of-flight and residual energy technique, the setup will allow the simultaneous measurement of the complementary fragment velocity and energy. The FALSTAFF setup and the upgrade of the first arm prototype with the new ionisation chamber CALIBER will be presented. The performances of the experimental apparatus is discussed. [ABSTRACT FROM AUTHOR]

Published

2018

3. Impact of material thicknesses on fission observables obtained with the FALSTAFF experimental setup.

Author

Thulliez, L., Doré, D., Berthoumieux, E., Panebianco, S., Legou, P., Kebbiri, M., Piret, Y., Mols, J. P., Combet, M., Riallot, M., Marcel, A., Farget, F., Pancin, J., Frégeau, M. O., Ledoux, X., Lecolley, F.-R., Perronnel, J., Goupillère, D., and Oberstedt, S.

Subjects

*NUCLEAR fission, *NUCLEAR reactors, *THERMAL fission, *IONIZATION chambers, *SPECTROMETERS

Abstract

In the past years, the fission studies have been mainly focused on thermal fission because most of the current nuclear reactors work in this energy domain. With the development of GEN-IV reactor concepts, mainly working in the fast energy domain, new nuclear data are needed. The FALSTAFF spectrometer under development at CEA-Saclay, France, is a two-arm spectrometer which will provide mass yields before (2V method) and after (EV method) neutron evaporation and consequently will have access to the neutron multiplicity as a function of mass. The axial ionization chamber, in addition to the kinetic energy value, will measure the energy loss profile of the fragment along its track. This energy loss profile will give information about the fragment nuclear charge. This paper will focus on recent developments on the FALSTAFF design. A special attention will be paid to the impact of the detector material thickness on the uncertainty of different observables. [ABSTRACT FROM AUTHOR]

Published

2017

4. Excitation-energy influence at the scission configuration.

Author

Ramos, D., Rodríguez-Tajes, C., Caamaño, M., Farget, F., Audouin, L., Benlliure, J., Casarejos, E., Clement, E., Cortina, D., Delaune, O., Derkx, X., Dijon, A., Doré, D., Fernández-Domínguez, B., de France, G., Heinz, A., Jacquot, B., Navin, A., Paradela, C., and Rejmund, M.

Subjects

NUCLEAR fission, NUCLEAR excitation, KINEMATICS, NEUTRONS, NUCLEAR fusion

Abstract

Transfer- and fusion-induced fission in inverse kinematics was proven to be a powerful tool to investigate nuclear fission, widening the information of the fission fragments and the access to unstable fissioning systems with respect to other experimental approaches. An experimental campaign for fission investigation has being carried out at GANIL with this technique since 2008. In these experiments, a beam of 238U, accelerated to 6.1 MeV/u, impinges on a 12C target. Fissioning systems from U to Cf are populated through transfer and fusion reactions, with excitation energies that range from few MeV up to 46MeV. The use of inverse kinematics, the SPIDER telescope, and the VAMOS spectrometer permitted the characterization of the fissioning system in terms of mass, nuclear charge, and excitation energy, and the isotopic identification of the full fragment distribution. The neutron excess, the total neutron multiplicity, and the even-odd staggering in the nuclear charge of fission fragments are presented as a function of the excitation energy of the fissioning system. Structure effects are observed at Z~50 and Z~55, where their impact evolves with the excitation energy. [ABSTRACT FROM AUTHOR]

Published

2017

5. Dependence of Fission-Fragment Properties On Excitation Energy For Neutron-Rich Actinides.

Author

Ramos, D., Rodríguez-Tajes, C., Caamaño, M., Farget, F., Audouin, L., Benlliure, J., Casarejos, E., Clement, E., Cortina, D., Delaune, O., Derkx, X., Dijon, A., Doré, D., Fernández-Domínguez, B., de France, G., Heinz, A., Jacquot, B., Navin, A., Paradela, C., and Rejmund, M.

Subjects

NUCLEAR fission, NUCLEAR fragmentation, NUCLEAR reactions, ACTINIDE elements, NEUTRONS

Abstract

Experimental access to full isotopic fragment distributions is very important to determine the features of the fission process. However, the isotopic identification of fission fragments has been, in the past, partial and scarce. A solution based on the use of inverse kinematics to study transfer-induced fission of exotic actinides was carried out at GANIL, resulting in the first experiment accessing the full identification of a collection of fissioning systems and their corresponding fission fragment distribution. In these experiments, a 238U beam at 6.14 AMeV impinged on a carbon target to produce fissioning systems from U to Am by transfer reactions, and Cf by fusion reactions. Isotopic fission yields of 250Cf, 244Cm, 240Pu, 239Np and 238U are presented in this work. With this information, the average number of neutrons as a function of the atomic number of the fragments is calculated, which reflects the impact of nuclear structure around Z=50, N=80 on the production of fission fragments. The characteristics of the Super Long, Standard I, Standard II, and Standard III fission channels were extracted from fits of the fragment yields for different ranges of excitation energy. The position and contribution of the fission channels as function of excitation energy are presented. [ABSTRACT FROM AUTHOR]

Published

2016

6. FISSION YIELDS OF MINOR ACTINIDES AT LOW ENERGY THROUGH MULTI-NUCLEON TRANSFER REACTIONS OF 238U ON 12C.

Author

RAMOS, D., RODRÍGUEZ-TAJES, C., CAAMAÑO, M., FARGET, F., AUDOUIN, L., BENLLIURE, J., CASAREJOS, E., CLEMENT, E., CORTINA, D., DELAUNE, O., DERKX, X., DIJON, A., DORÉ, D., FERNÁNDEZ-DOMÍNGUEZ, B., DE FRANCE, G., HEINZ, A., JACQUOT, B., NAVIN, A., PARADELA, C., and REJMUND, M.

Subjects

ATOMIC excitation, NUCLEAR fission, KINEMATICS, ACTINIDE elements, ENERGY levels (Quantum mechanics)

Abstract

First preliminary results of fragments distribution as a function of the excitation energy for different fissioning systems from U to Cm and 250Cf are presented. A new method based on inverse kinematics to study transferinduced fission of minor actinides was carried out in GANIL in 2008, and again in 2011. In these experiments, a 238U beam at 6.1 A MeV impinged on a carbon target to produce fissioning systems by multi-nucleon transfer reactions, resulting in the first experiments accessing the full identification of a collection of fissioning systems and their corresponding fission fragments distribution. The excitation energy is deduced from the detection of the recoil nucleus in an angular DE-E stripped silicon telescope, and the identification of the fragments is made possible by the VAMOS spectrometer. [ABSTRACT FROM AUTHOR]

Published

2015

7. Delayed neutron measurements of 232Th neutron-induced fission.

Author

Ledoux, X., Doré, D., Mosconi, M., Nolte, R., Roettger, S., and Varet, S.

Subjects

*NEUTRONS, *THORIUM, *NUCLEAR fission, *NUCLEAR reactors, *DATA analysis

Abstract

Delayed neutrons (DN) play an important role in nuclear reactor physics. Innovative critical reactor studies bring to light the need of new DN yields data. For the thorium fuel cycle DN data for 232 Th is needed. In the literature, significant discrepancies were observed for energies below 4 MeV and data are dispersed around 14 MeV. Therefore DN absolute yields from 232 Th fission have been determined at the PTB Ion Accelerator Facility in Braunschweig. A consistent set of data has been measured for incident neutrons with energies of 2, 3, 4, 6, 7, 10 and 16 MeV. [ABSTRACT FROM AUTHOR]

Published

2015

8. Development of a Micromegas TPC for Low Energy Heavy Ions Measurement for Nuclear Fission and Astrophysics Applications.

Author

Panebianco, S., Axiotis, M., Doré, D., Fanourakis, G., Geralis, Th., Giomataris, I., Harissopoulos, S., Lagoyannis, A., Papaevangelou, Th., and Vernoud, L.

Subjects

HEAVY ions, ENERGY levels (Quantum mechanics), PHYSICAL measurements, NUCLEAR fission, NUCLEAR astrophysics, PARTICLES (Nuclear physics), NUCLEAR physics

Abstract

Time Projection Chambers are widely used since many years for tracking and identification of charged particles in high energy physics. We present a new R&D project to investigate the feasibility of a Micromegas TPC for low energy heavy ions detection. Two physics cases are relevant for this project. The first is the study of the nuclear fission of actinides by measuring the fission fragments properties (mass, nuclear charge, kinetic energy) that will be performed at different installations and in particular at the NFS facility to be built in the framework of the SPIRAL2 project in GANIL. The second physics case is the study of heavy ion reactions, like (α,γ), (α,p), (α,n) and all the inverse reactions in the energy range between 1.5 and 3 AMeV using both stable and radioactive beams. These reactions have a key role in p process in nuclear astrophysics to explain the synthesis of heavy proton-rich nuclei. Within the project, a large effort is devoted to Monte-Carlo simulations and a detailed benchmark of different simulation codes on the energy loss and range in gas of heavy ions at low energy has been performed. A new approach for simulating the ion charge state evolution in GEANT4 is also presented. Finally, preliminary results of an experimental test campaign on prototype are discussed. [ABSTRACT FROM AUTHOR]

Published

2011

9. Delayed Neutrons from High Energy Fission-Spallation Reactions.

Author

Ridikas, D., Bokov, P., David, J.-C., Doré, D., Giacri, M.-L., Ledoux, X., Plukis, A., Plukiene, R., and Van Lauwe, A.

Subjects

NEUTRONS, NUCLEAR fission, NUCLEAR reactions, NUCLEAR physics, NEUTRINOS

Abstract

The next generation spallation neutron sources, neutrino factories or RIB production facilities currently being designed and constructed world wide will increase the average proton beam power on target by a few orders of magnitude. Increased proton beam power results in target thermal hydraulic issues leading to new target designs, very often based on liquid metal technologies such as Hg, Pb, or PbBi. Radioactive nuclides produced in liquid metal targets are transported into hot cells, into pumps or close to electronics with radiation sensitive components. Besides the considerable amount of photon activity in the irradiated liquid metal, a significant amount of the Delayed Neutron (DN) precursor activity can be accumulated in the target fluid. The transit time from the front of a liquid metal target into areas, where DNs may be important, can be as short as a few seconds, i.e. well within one half-life of many DN precursors. Therefore, it seems very important to evaluate the DN flux as a function of position and determine if DNs may contribute significantly to the activation and dose rates. The multi-particle transport code MCNPX combined with the material evolution program CINDER’90 is used to predict the DN precursors and construct the DN tables. These DN tables are employed within the generalized geometrical model of the MegaPie spallation target at PSI (Switzerland). We show that the contribution of DNs and prompt spallation neutrons to the total neutron flux is comparable at the very top of the liquid PbBi loop. We also demonstrate that these estimates of DNs within MCNPX are very much model-dependent. No experimental data are available for DN yields and time spectra from high energy fission-spallation reactions. An experiment to perform these measurements is proposed. © 2005 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2005

10. Fission Fragment Distributions and Delayed Neutron Yields from Photon-Induced-Fission.

Author

David, J.-C., Doré, D., Giacri-Mauborgne, M.-L., Ridikas, D., and Van Lauwe, A.

Subjects

*NUCLEAR fission, *NUCLEAR reactions, *NUCLEAR energy, *ION bombardment, *COLLISIONS (Nuclear physics), *NUCLEAR physics, *PHYSICS

Abstract

Fission fragment distributions and delayed neutron yields for 235U and 238U are provided by a complete modelization of the photofission process below 25 MeV. The absorption cross-section parameterization and the fission fragment distributions are given and compared to experimental data. The delayed neutron yields and the half-lives in terms of six groups are presented and compared to data obtained with a bremsstrahlung spectrum of 15 MeV. © 2005 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2005

11. Dynamical effects and time scale in fission processes in nuclear collisions in the fermi energy range.

Author

Colin, J., Bocage, F., Louvel, M., Auger, G., Bacri, Ch. O., Bellaize, N., Borderie, B., Bougault, R., Brou, R., Buchet, P., Charvet, J. L., Chbihi, A., Cussol, D., Dayras, R., Demeyer, A., Doré, D., Durand, D., Frankland, J. D., Galichet, E., and Genouin-Duhamel, E.

Subjects

COLLISIONS (Nuclear physics), FERMI energy, NUCLEAR matter, ANGULAR momentum (Nuclear physics), NUCLEAR fission

Published

2000

12. Measurement of delayed neutron yields and time spectra from 1 GeV protons interacting with thick natPb targets.

Author

Ridikas, D., Barzakh, A., Blideanu, V., David, J. C., Doré, D., Fedorov, D., Ledoux, X., Moroz, F., Panteleev, V., Plukiene, R., Plukis, A., Prévost, A., Shcherbakov, O., and Vorobyev, A.

Subjects

DELAYED neutrons, BARYONS, NUCLEAR fission, RADIOACTIVE substances, LIQUID metals

Abstract

In this paper we present for the first time the measured delayed neutron (DN) yields and time spectra from high-energy protons interacting with thick natPb targets. The 1GeV protons from the accelerator impinged on targets of different thicknesses producing a huge number of spallation-fission products, some of which can be DN precursors. After the beam is switched off, the DNs were detected with optimized 3He counter. The production yields of light DN precursors as 17N and “usual” fission products as 87Br and 88Br, which dominate the total DN activity, are obtained both for thin and thick targets. These new data are of great interest for the new generation high-power spallation targets based on liquid-metal technologies. Our findings also should help to constrain the physics models within the simulations codes. [ABSTRACT FROM AUTHOR]

Published

2007

13. Delayed gamma studies from photo-fission of 237Np for nuclear waste characterization

Author

Dighe, P.M., Berthoumieux, E., Doré, D., Laborie, J.M., Ledoux, X., Macary, V., Panebianco, S., and Ridikas, D.

Subjects

*GAMMA decay, *NEUTRONS, *PHOTONUCLEAR reactions, *RADIOACTIVE wastes, *NEPTUNIUM, *BARRELS, *NONDESTRUCTIVE testing, *BREMSSTRAHLUNG, *NUCLEAR fission

Abstract

Abstract: An active and non-destructive method is being established for detection of 237Np in nuclear waste barrels. The unique high energy decay gamma signature produced after photo-fission is analysed to deduce decay time parameters. A high purity 237Np sample was irradiated with bremsstrahlung photons and high energy gamma decay spectra were measured with BGO detectors for various irradiation durations. The analysis of decay spectra resulted in the formation of five decay groups, which can reproduce the experimental decay spectra within 10% accuracy. These parameters together with neutron decay groups are absolutely essential to quantify the nuclear material in waste barrels by photo-fission. The delayed decay gamma groups for 237Np nucleus are being reported for the first time. [Copyright &y& Elsevier]

Published

2009

14. Transfer reactions in inverse kinematics: An experimental approach for fission investigations.

Author

Rodríguez-Tajes, C., Farget, F., Derkx, X., Caamaño, M., Delaune, O., Schmidt, K. -H., Clément, E., Dijon, A., Heinz, A., Roger, T., Audouin, L., Benlliure, J., Casarejos, E., Cortina, D., Doré, D., Fernández-Domínguez, B., Jacquot, B., Jurado, B., Navin, A., and Paradela, C.

Subjects

*KINEMATICS, *NUCLEAR fission, *INELASTIC collisions, *TELESCOPES, *ATOMIC nucleus, *NUCLEAR excitation

Abstract

Inelastic and multinucleon transfer reactions between a 238U beam, accelerated at 6.14 MeV/u, and a 12C target were used for the production of neutron-rich, fissioning systems from U to Cm. A Si telescope, devoted to the detection of the targetlike nuclei, provided a characterization of the fissioning systems in atomic and mass numbers, as well as in excitation energy. Cross sections and angular and excitation-energy distributions were measured for the inelastic and transfer channels. Possible excitations of the targetlike nuclei were experimentally investigated for the first time, by means of γ-ray measurements. The decays from the first excited states of 12C, 11B, and 10Be were observed with probabilities of 0.12-0.14, while no evidence for the population of higher-lying states was found. Moreover, the fission probabilities of 238U, 239Np and 240,241,242pu and 244Cm were determined as a function of the excitation energy. [ABSTRACT FROM AUTHOR]

Published

2014

15. Isotopic fission-fragment distributions of 238U, 239Np, 240Pu, 244Cm, and 250Cf produced through inelastic scattering, transfer, and fusion reactions in inverse kinematics.

Author

Ramos, D., Caamaño, M., Farget, F., Rodríguez-Tajes, C., Audouin, L., Benlliure, J., Casarejos, E., Clement, E., Cortina, D., Delaune, O., Derkx, X., Dijon, A., Doré, D., Fernández-Domínguez, B., de France, G., Heinz, A., Jacquot, B., Navin, A., Paradela, C., and Rejmund, M.

Subjects

*INELASTIC scattering, *NUCLEAR fission, *NUCLEAR fusion

Abstract

Transfer- and fusion-induced fission in inverse kinematics has proved to be a powerful tool to investigate nuclear fission, widening information on the fission fragments and access to unstable fissioning systems with respect to other experimental approaches. An experimental campaign is being carried out at GANIL with this technique since 2008. In these experiments, a beam of 238U, accelerated to 6.1 MeV/u, impinges on a 12C target. Fissioning systems from U to Cf are populated through inelastic scattering, transfer, and fusion reactions, with excitation energies that range from a few MeV up to 46 MeV. The use of inverse kinematics, the SPIDER telescope, and the VAMOS spectrometer allow the characterization of the fissioning system in terms of mass, nuclear charge, and excitation energy, and the isotopic identification of the full fragment distribution. This work reports on new data from the second experiment of the campaign on fission-fragment yields of the heavy actinides 238U, 239Np, 240Pu, 244Cm, and 250Cf, which are of interest from both fundamental and application points of view. [ABSTRACT FROM AUTHOR]

Published

2018