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Minehara, E.J.

Paper Title Page
MOPEA034 Study of Positron Production System using Superconducting Electron Linac 142
 
  • N. Hayashizaki
    RLNR, Tokyo
  • R. Kuroda, B.E. O'Rourke, N. Oshima, R. Suzuki
    AIST, Tsukuba, Ibaraki
  • E.J. Minehara
    WERC, Tsuruga , Fukui
 
 

Positron that is the antiparticle of the electron, by the specific character, can evaluate vacant spaces in microstructure from atomic level to nanometer level, which is difficult in other measurement methods. In the case of high functional material, this structure often relates directly to the performance, and the evaluation method that uses the positron beam is expected as a useful measurement tool to develop a new material. If it is able to produce more high-intense and low-energy positron beam with an accelerator, the microstructure evaluation is carried out in prompt and high accuracy for various demands of the material analysis. We have studied a positron production system using a superconducting electron linac instead of normal conducting one. Electron beam accelerated with the superconducting linac is irradiated on tantalum and converted to bremstrahlung photons, and positron beam is produced by pair creation of them. The designed acceleration energy of the superconducting electron linac is 15-40 MeV and the maximum beam power is 10 kW. The system configuration and the progress status will be presented.

 
MOPD019 Tandem Accelerator as the Injector for the Medical-use Synchrotron at the Wakasa-wan Energy Research Center 714
 
  • S. Hatori, S. Fukumoto, Y. Hayashi, H. Kagawa, T. Kurita, E.J. Minehara, S. Nagasaki, Y. Nakata, T. Odagiri, M. Shimada, H. Yamada, F. Yamaguchi, H. Yamamoto, M. Yodose
    WERC, Tsuruga , Fukui
 
 

We have operated the accelerator system which consists of a tandem accelerator and a synchrotron since the completion of the construction and beam commissioning at the Wakasa-wan Energy Research Center, Tsuruga, Japan in 2000. The acceleration voltage of the tandem accelerator amounts to 5 MV and is generated by the Dynamitron-type cascade voltage doubler rectifier. The beam from the tandem accelerator is transported to the MeV-ion experimental area for the irradiation to the industrial or biological material and for the ion beam analysis. The tandem beam is also injected to the 200 MeV proton synchrotron. The synchrotron beam has been used for the high energy irradiation and the cancer therapy. The tandem accelerator is used for a lot of purposes including cancer therapy, therefore, stable operation of the system and efficient sharing of the operation duration are required. Developments of the accelerator are presented putting a stress on the stable and efficient operation of the system in this paper.