• A. Noda, Y. Iwashita, H. Souda, H. Tongu, A. Wakita
  Kyoto ICR, Uji, Kyoto
• H. Daido, M. Ikegami, H. Kiriyama, M. Mori, M. Nishiuchi, K. Ogura, S. Orimo, A. Sagisaka, A. Yogo
  JAEA/Kansai, Kizu-machi Souraku-gun Kyoto-fu
• A. Pirozhkov
  JAEA, Ibaraki-ken
• T. Shirai
  NIRS, Chiba-shi

Funding: This work is supported by Advanced Compact Accelerator project by MEXT of Japanese Government and 21COE of Kyoto University, Center for Diversity and Universality in Physics.
By the phase rotation with the use of rf electric fields created by two gap resonator synchronous to a pulse laser, the energy spread of the laser-produced ions can be reduced*. In addition, owing to the curved structure of the electric field line in the gaps of the phase rotator, radial focusing effect is found also to exist. In order to extend the applicable energy of the phase rotation to the region where such laser produced protons can be directly applied for cancer therapy, multi-gap resonator with higher frequency has been proposed. By controlling the relative phases between the pulse laser and the electric fields in the gaps of phase rotator, we can create peaks in the energy spectrum simultaneously focusing in the radial direction.

* Japanese Journal of Applied Physics (Express Letter), 46 (2007) L717-L720

• M. Yamada, H. Fujisawa, M. Ichikawa, Y. Iwashita, H. Tongu
  Kyoto ICR, Uji, Kyoto
• P. Geltenbort
  ILL, Grenoble
• K. Hirota, Y. Otake, H. Sato
  RIKEN, Wako, Saitama
• T. Ino, K. Mishima, T. Morishima, S. Mutou, H.M. Shimizu, K. Taketani
  KEK, Tsukuba
• Y. Kamiya, S. Kawasaki, S. Komamiya, H. Otono, S. Yamashita
  University of Tokyo, Tokyo
• T. Oku, K. Sakai, T. Shinohara, J. Suzuki
  JAEA, Ibaraki-ken
• Y. Seki
  Kyoto University, Kyoto
• T. Yoshioka
  ICEPP, Tokyo

We are developing a modulating permanent magnet sextupole lens to focus pulsed cold neutrons. It is based on the extended Halbach configuration to generate stronger magnetic field. In order to adjust the strength, the magnet is divided into two nested co-axial rings, where the inner ring is fixed and the outer ring can be rotated. Synchronizing the modulation with neutron beam pulse suppresses the chromatic aberration. These devices largely improve the utilization efficiency of neutrons, which makes even small linac based neutron sources practical. We have fabricated a half-scale model and studied its strength, torque and temperature rise during the operation. The main causes of the temperature rise are eddy-current loss in the poles made of soft magnetic material in inner ring and hysteresis loss. A laminated structure reduced the eddy-current loss. The temperature rise was suppressed to about half of the former model. We now study their B-H curve to optimize the thickness of the sheet. Annealing of the material is supposed to reduce the hysteresis loss, which will be tested soon. The experimental results of very-cold neutrons focusing with the half-scale model are also described.

Slides

• M. Ichikawa, H. Fujisawa, Y. Iwashita, T. Sugimoto, H. Tongu, M. Yamada
  Kyoto ICR, Uji, Kyoto

We aim to develop a small and high intensity proton source for a compact accelerator based neutron source. Because this proton source shall be located close to RFQ for simplification, ratio of H⁺ to molecular ions such as H²⁺ or H³⁺ must be large. Therefore we select ECR ion source with permanent magnet as a small and high intensity ion source. ECR ion sources can provide high H⁺ ratio because of their high plasma temperature. Using permanent magnets makes the ion source small and running cost low. Because there is no hot cathode, longer MTBF is expected. Usually, gas is fed into ion sources continuously, even if ion sources run in pulse operation mode. But, continuous gas flow doesn't make vacuum in good level. So, we decided to install pulse gas valve directly to the plasma chamber. Feeding the gas only when the ion source is in operation reduces the gas load to the evacuation system and the vacuum level can be kept high. Recent experimental results will be presented.