Author: Jeon, D.
Paper Title Page
THA02 Overview of the RISP Superconducting Linac 197
  • D. Jeon, Y. Chung, H.J. Kim, S.K. Kim
    IBS, Daejeon, Republic of Korea
  • E.-S. Kim
    KNU, Deagu, Republic of Korea
  • J.-W. Kim
    NCC, Korea, Kyonggi, Republic of Korea
  • Y.Y. Lee
    BNL, Upton, Long Island, New York, USA
  The Rare Isotope Science Project (RISP) got launched December 2011 which consists of In-Flight Fragmentation Facility and ISOL facility, providing uniques research opportunities in broad range of sciences. The superonducting driver linac can accelerate up to 200 MeV/u for uranium beam and up to 600 MeV for proton beam. The ISOL post linac which is also a superconducting linac. Design parameters and choices are presented.  
slides icon Slides THA02 [3.085 MB]  
THB03 Design Sudy for Front-End System at Rare Isotope Science Project (RISP) 207
  • E.-S. Kim
    KNU, Deagu, Republic of Korea
  • J. Bahng, J.G. Hwang, S.W. Jang
    Kyungpook National University, Daegu, Republic of Korea
  • B. Choi, D. Jeon, B. Kim, H. Kim, S.K. Kim
    IBS, Daejeon, Republic of Korea
  Heavy ion beams of 400 kW and 70 kW are generated at the RISP by in-flight and ISOL methods, respectively. Front-End system in the RISP consists of 28 GHz superconducting ECR-IS with 10 keV/u, LEBT with two-bends and a multi-harmonic buncher, a RFQ with 81.25 MHz and 300 keV/u, and MEBT with two re-bunchers. The design studies have been performed to optimize the beam and accelerator parameters to meet the required design goals. It is shown that the front-end simulations results can provide the two-charge state beams up to uranium to upstream linac with the required beam emittances. In this paper, we present the design results for the front-end system and on the beam dynamics.  
slides icon Slides THB03 [1.942 MB]