Fabrication of advanced targets for laser driven nuclear fusion reactions through standard microelectronics technology approaches

Silicon targets enriched with hydrogen and doped with boron at high atomic concentration (1020–1022 cm−3) were designed and fabricated using ion implantation and thermal diffusion processes to be used for experiments in the field of laser driven nuclear fusion. Two main types of target were prepared...

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Bibliographic Details
Published inJournal of instrumentation Vol. 12; no. 10; p. P10001
Main Authors Picciotto, A., Crivellari, M., Bellutti, P., Barozzi, M., Kucharik, M., Krasa, J., Swidlosky, A., Malinowska, A., Velyhan, A., Ullschmied, J., Margarone, D.
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 02.10.2017
Subjects
Acceleration
Alpha particles
Alpha rays
Boron
Foils
Ion implantation
Lasers
Nuclear fusion
Nuclear reactions
Thermal diffusion
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Summary:Silicon targets enriched with hydrogen and doped with boron at high atomic concentration (1020–1022 cm−3) were designed and fabricated using ion implantation and thermal diffusion processes to be used for experiments in the field of laser driven nuclear fusion. Two main types of target were prepared: thin (2 μm) foils and thick (500 μm) slabs. Such targets were irradiated with a sub-nanosecond, kJ-class laser with a moderate intensity (∼1016 W/cm2) to trigger the p(11B,α)2α nuclear fusion reaction thanks to the acceleration of proton streams with energy of 0.1–1 MeV . The combination of the ad-hoc developed targets and the given laser pulse parameters allowed to generate a very high flux of alpha particles (107–109/sr per shot). The paper mainly focuses on microfabrication techniques and processes optimized for the fabrication of such advanced targets and on a comparison of the key results achieved with the different targets used in the experiment. Hydrodynamic simulations are also discussed.
ISSN:1748-0221
1748-0221
DOI:10.1088/1748-0221/12/10/P10001