EPJ Web of Conferences (Jan 2017)

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

  • 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.,
  • Oberstedt S.

DOI
https://doi.org/10.1051/epjconf/201714604028
Journal volume & issue
Vol. 146
p. 04028

Abstract

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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.