RUPAC2018 - List of Authors (Bashevoy, V.)

Paper	Title	Page
TUPSA40	DC130: Next Step of the FLNR Accelerator Complex for Applied Science Activity
	S.V. Mitrofanov, P.Yu. Apel, V. Bashevoy, V. Bekhterev, S.L. Bogomolov, O.N. Borisov, J. Franko, G.G. Gulbekyan, I.A. Ivanenko, I.V. Kalagin, N.Yu. Kazarinov, V. Mironov, V.A. Semin, V.A. Skuratov, A. Tikhomirov JINR, Dubna, Moscow Region, Russia
	The main activities of Flerov Laboratory of Nuclear Reactions, following its name - are related to fundamental science, but, in parallel, plenty of efforts are paid for practical applications. Certain amount of beam time every year is spent for applied science experiments on FLNR accelerator complex. For the moment, the main directions are: the production of the heterogeneousμ- and nano-structured materials; testing of electronic components (avionics and space electronics) for radiation hardness; ion-implantation nanotechnology and radiation materials science. Basing on FLNR long term experience in these fields and aiming to improve the instrumentation, the accelerator department start the Design Study for new cyclotron DC130 which will be dedicated machine for applied researches in FLNR. Following the user's requirements DC130 should accelerate the heavy ions with mass-to-charge ratio A/Z of the range from 5 to 8 up to fixed energies 2 and 4.5 MeV per unit mass. The first outlook of DC130 parameters, its features, layout of its casemate and general overview of the new FLNR facility for applied science will be presented.
	Poster TUPSA40 [1.675 MB]
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TUPSA60	Beam Lines for Gas Filled Separator Experiments at DC280 Cyclotron	272
	N.Yu. Kazarinov, V. Bashevoy, A. Eremin, G.G. Gulbekyan, G.N. Ivanov, I.V. Kalagin, V.I. Kazacha, N.F. Osipov, V. Utenkov JINR, Dubna, Moscow Region, Russia Lisov, V.I. Lisov JINR/FLNR, Moscow region, Russia
	The design of two beam lines for ion transportation from cyclotron DC280 to Gas Filled Separators (GSF) is presented. The beam lines include commutating magnet with variable magnetic field induction up to 1.5 T that gives the possibility to bend ion beams in five directions providing ion transportation through beam lines to five experimental setups. The beam focusing in the beam lines is provided by set of quadrupole lenses having the gradients up to 7.7 T/m. The beam lines are intended for the efficient ion transportation of elements from Helium to Uranium with the atomic mass to charge ratio in the range of 4-7.5 at energies from 4 up to 8 MeV/amu. The ion beam power will reach the value about 3 kW. The water cooled current aperture diaphragms will be installed into all beam lines to prevent the tube damage. The beam diagnostics consists of the Faraday caps (FC), slit collimators, sector aperture diaphragms and ionization beam profile monitors. A new structure of the beam line #3 and calculation results for 48Ca⁹⁺ and 48Ca⁷⁺ ion beam transportation from the extraction point to the new gas-filled separator GFS2 are listed. In addition, a new structure of the beam line #4 and calculation results for 48Ca⁸⁺, 50Ti⁸⁺, and 54Cr⁹⁺ ion beam transportation from the extraction point to the new GFS3 are presented.
DOI •	reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-TUPSA60
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Paper

Title

Page

TUPSA40

DC130: Next Step of the FLNR Accelerator Complex for Applied Science Activity

S.V. Mitrofanov, P.Yu. Apel, V. Bashevoy, V. Bekhterev, S.L. Bogomolov, O.N. Borisov, J. Franko, G.G. Gulbekyan, I.A. Ivanenko, I.V. Kalagin, N.Yu. Kazarinov, V. Mironov, V.A. Semin, V.A. Skuratov, A. Tikhomirov
JINR, Dubna, Moscow Region, Russia

The main activities of Flerov Laboratory of Nuclear Reactions, following its name - are related to fundamental science, but, in parallel, plenty of efforts are paid for practical applications. Certain amount of beam time every year is spent for applied science experiments on FLNR accelerator complex. For the moment, the main directions are: the production of the heterogeneousμ- and nano-structured materials; testing of electronic components (avionics and space electronics) for radiation hardness; ion-implantation nanotechnology and radiation materials science. Basing on FLNR long term experience in these fields and aiming to improve the instrumentation, the accelerator department start the Design Study for new cyclotron DC130 which will be dedicated machine for applied researches in FLNR. Following the user's requirements DC130 should accelerate the heavy ions with mass-to-charge ratio A/Z of the range from 5 to 8 up to fixed energies 2 and 4.5 MeV per unit mass. The first outlook of DC130 parameters, its features, layout of its casemate and general overview of the new FLNR facility for applied science will be presented.

Poster TUPSA40 [1.675 MB]

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TUPSA60

Beam Lines for Gas Filled Separator Experiments at DC280 Cyclotron

272

N.Yu. Kazarinov, V. Bashevoy, A. Eremin, G.G. Gulbekyan, G.N. Ivanov, I.V. Kalagin, V.I. Kazacha, N.F. Osipov, V. Utenkov
JINR, Dubna, Moscow Region, Russia
Lisov, V.I. Lisov
JINR/FLNR, Moscow region, Russia

The design of two beam lines for ion transportation from cyclotron DC280 to Gas Filled Separators (GSF) is presented. The beam lines include commutating magnet with variable magnetic field induction up to 1.5 T that gives the possibility to bend ion beams in five directions providing ion transportation through beam lines to five experimental setups. The beam focusing in the beam lines is provided by set of quadrupole lenses having the gradients up to 7.7 T/m. The beam lines are intended for the efficient ion transportation of elements from Helium to Uranium with the atomic mass to charge ratio in the range of 4-7.5 at energies from 4 up to 8 MeV/amu. The ion beam power will reach the value about 3 kW. The water cooled current aperture diaphragms will be installed into all beam lines to prevent the tube damage. The beam diagnostics consists of the Faraday caps (FC), slit collimators, sector aperture diaphragms and ionization beam profile monitors. A new structure of the beam line #3 and calculation results for 48Ca⁹⁺ and 48Ca⁷⁺ ion beam transportation from the extraction point to the new gas-filled separator GFS2 are listed. In addition, a new structure of the beam line #4 and calculation results for 48Ca⁸⁺, 50Ti⁸⁺, and 54Cr⁹⁺ ion beam transportation from the extraction point to the new GFS3 are presented.

DOI •

reference for this paper ※ https://doi.org/10.18429/JACoW-RUPAC2018-TUPSA60

Export •

reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)