Author: Bakinowskaya, A.A.
Paper Title Page
MOPVA087 Low Betta Superconducting Cavity for the New Injector Linac for Nuclotron-NICA 1058
 
  • M. Gusarova, T.A. Bakhareva, M.V. Lalayan, S.V. Matsievskiy, N.P. Sobenin, D.V. Surkov, K.V. Taletskiy, V. Zvyagintsev
    MEPhI, Moscow, Russia
  • A.A. Bakinowskaya, V.S. Petrakovsky, A.I. Pokrovsky, D.A. Shparla
    Physical-Technical Institute of the National Academy of Sciences of Belarus, Minsk, Belarus
  • A.V. Butenko, G.V. Trubnikov
    JINR/VBLHEP, Dubna, Moscow region, Russia
  • V. Zvyagintsev
    TRIUMF, Vancouver, Canada
 
  The results of the RF, mechanical and multipactor discharge simulations of the 162 MHz quarter wave resonator (QWR) for New Superconducting Injector Linac for Nuclotron-NICA are presented. Cavity design in conjunction with manufacturing features is discussed.  
DOI • reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2017-MOPVA087  
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MOPVA088 Medium Betta Superconducting Cavity for the New Injector Linac for Nuclotron-NICA 1061
 
  • M. Gusarova, M.V. Lalayan, N.P. Sobenin, D.V. Surkov, K.V. Taletskiy
    MEPhI, Moscow, Russia
  • A.A. Bakinowskaya, V.S. Petrakovsky, A.I. Pokrovsky, D.A. Shparla
    Physical-Technical Institute of the National Academy of Sciences of Belarus, Minsk, Belarus
  • A.V. Butenko, G.V. Trubnikov
    JINR/VBLHEP, Dubna, Moscow region, Russia
 
  The results of the electrodynamical and multipactor discharge simulations of the medium betta superconducting cavity for New Superconducting Injector Linac for Nuclotron-NICA are presented. Different designs of CH and Spoke cavities are compared and the optimal one is chosen.  
DOI • reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2017-MOPVA088  
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WEPVA014 Status of R&D on New Superconducting Injector Linac for Nuclotron-NICA 3282
 
  • G.V. Trubnikov, A.V. Butenko, N. Emelianov, A.O. Sidorin, E. Syresin
    JINR, Dubna, Moscow Region, Russia
  • T.A. Bakhareva, M. Gusarova, T. Kulevoy, S.V. Matsievskiy, S.M. Polozov, A.V. Samoshin, N.P. Sobenin, D.V. Surkov, K.V. Taletskiy, S.E. Toporkov, V. Zvyagintsev
    MEPhI, Moscow, Russia
  • A.A. Bakinowskaya, A.A. Marysheva, V.S. Petrakovsky, I.L. Pobol, A.I. Pokrovsky, D.A. Shparla, S.V. Yurevich, V.G. Zaleski
    Physical-Technical Institute of the National Academy of Sciences of Belarus, Minsk, Belarus
  • M.A. Baturitski, S.A. Maksimenko
    INP BSU, Minsk, Belarus
  • S.E. Demyanov
    Scientific-Practical Materials Research Centre of the National Academy of Sciences of Belarus, Minsk, Belarus
  • V.A. Karpovich
    BSU, Minsk, Belarus
  • T. Kulevoy, S.M. Polozov
    ITEP, Moscow, Russia
  • A.A. Kurayev, V.V. Matbeenko, A.O. Rak
    Belarus State University of Informatics and Radioelectronics (BSUIR), Minsk, Belarus
  • V.N. Rodionova
    Belarussian State University, Scientific Research Institute of Nuclear Problems, Minsk, Belarus
  • A.O. Sidorin
    Saint Petersburg State University, Saint Petersburg, Russia
  • V. Zvyagintsev
    TRIUMF, Vancouver, Canada
 
  The new collaboration of JINR, NRNU MEPhI, INP BSU, PTI NASB, BSUIR and SPMRC NASB starts in 2015 the project of linac-injector design in 2015. The goal of new linac is to accelerate protons up to 25 MeV (and up to 50 MeV at the second stage) and light ions to ~7.5 MeV/u for Nuclotron-NICA injection. Current results of the linac general design and development, beam dynamics simulations, SC cavities design and SRF technology development are presented in this report.  
DOI • reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2017-WEPVA014  
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