Author: Shirkov, G.
Paper Title Page
MOB02
 Linear Electron Accelerator LINAC-200, Status of Work and Prospects  
 
  • V.V. Kobets, M. Gostkin, M.A. Nozdrin, Y.A. Samofalova, G. Shirkov, A. Trifonov, K. Yunenko, A. Zhemchugov
    JINR, Dubna, Moscow Region, Russia
  • A.E. Brukva
    JINR/DLNP, Dubna, Moscow region, Russia
  • V. Shabratov
    JINR/VBLHEP, Moscow, Russia
  
  The LINAC-200 linear electron accelerator is created on the basis of the MEA accelerator transported to JINR from NIKHEF (Netherlands) In August 2017, the physical launch of the LINAC-200 facility (the first stage of the LINAC-800 facility) with an electron energy of 220 MeV was carried out. The accelerator operates in a pulsed mode. The duration of the current pulse is 0.1 - 3.0 mcs, the amplitude is from 40 mA to single electrons. The energy of electrons can be smoothly changed within the range of 30 - 200 MeV. This makes it possible to use the accelerator for testing detectors, as well as for studies of the radiation resistance of materials and other works.  
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MOPSA33
 Superconducting Cyclotron SC230 for Flash Proton Therapy Studies  
 
  • O. Karamyshev, K. Bunyatov, S. Gurskiy, G.G. Hodshibagijan, G.A. Karamysheva, G.V. Mytzin, M.S. Novikov, D. Popov, G. Shirkov, S.G. Shirkov, G.V. Trubnikov, S. Yakovenko
    JINR, Dubna, Moscow Region, Russia
  • I.D. Lyapin, V. Malinin
    JINR/DLNP, Dubna, Moscow region, Russia
  
  In recent years, intensive research on the FLASH radiation therapy method has been carried out all over the world. Specialists have a great interest in the FLASH proton therapy method since it not only reduces the effect on healthy tissues but also reduces the number of treatment procedures. However, before proton FLASH therapy can be fully implemented in practice, it is necessary to solve a number of engineering and technical challenges. There is a need for an accelerator that provides an average beam current of 500-100000 nA for the entire range of energies used in treatment. This intensity is not achievable with commercial machines, designed to minimize the size of the installation and provide an intensity sufficient for standard treatment (100-400 nA). We are starting work on the biomedical center with the creation of an accelerator, that is innovative in many ways. In addition to the possibility of obtaining a high-intensity beam, the accelerator will have the lowest energy consumption among accelerators of the same class. The project was developed with an eye to the possibility of using a high-temperature superconductor (HTS), therefore, SC230 could become the world’s first medical cyclotron with an HTS coil.  
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