Beam-facing material selection for mitigation of residual doses in the HEBT of IFMIF-DONES
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Elsevier
Materia
IFMIF-DONES Particle accelerator Beam facing material
Fecha
2024-01-17Referencia bibliográfica
Ogando, Francisco, et al. Beam-facing material selection for mitigation of residual doses in the HEBT of IFMIF-DONES. Nuclear Materials and Energy 38 (2024) 101592 [10.1016/j.nme.2024.101592]
Patrocinador
European Union via the Euratom Research and Training Programme (Grant Agreement No 101052200 — EUROfusion); ETSII-UNEDResumen
IFMIF-DONES will be an irradiation facility based on a 40 MeV deuteron accelerator. Unavoidable beam losses
along the accelerator result in deuterium interactions with the beam facing materials of the vacuum beam pipe,
some of them leading to material activation. The initial design of the beam pipe was based on stainless steel,
but an evaluation of the residual doses from the pipe showed high values after operation of the accelerator.
The accelerator beam line must be periodically maintained, and excessive cooling times for reaching acceptable
dose levels may result in poorer availability of the facility. A deeper study of the High Energy Beam Transport
line (HEBT) showed that a direct reaction between deuterons and iron in steel resulted in the production of
Co-56, with a half-life of 77 days. This radioisotope is the main source of the radiation and makes it impractical
to wait for a proper attenuation of the radiation field. A redesign of beam line elements has been performed to
avoid the presence of stainless steel as a beam facing material and to replace it with aluminum where possible,
resulting in faster decay of residual doses. This work contains a summary of the nuclear analysis performed for
the computation of residual doses with stainless steel beam pipe, stressing the uncertainties of the calculations,
based on the limited availability of nuclear data for the relevant nuclear reaction Fe56 (d,2n). The proposed
replacement of element materials is also described, and an updated nuclear analysis shows the reduction of
residual radiation, and its impact on possible maintenance operations.