Author: Chen, Y.-J.
Paper Title Page
WEPC043 Beam Transport in a Dielectric Wall Accelerator for Intensity Modulated Proton Therapy 2106
 
  • Y.-J. Chen, D.T. Blackfield, S.D. Nelson, B. R. Poole
    LLNL, Livermore, California, USA
 
  Funding: This work performed under the auspices of the U. S. Department of Energy by Lawrence Livermore National Laboratory under Contract DE-AC52-07NA2A27344.
We are de­vel­op­ing a com­pact di­elec­tric wall ac­cel­er­a­tor (DWA) for in­ten­si­ty mod­u­lat­ed pro­ton ther­a­py (IMPT) with a goal of fit­ting the com­pact pro­ton DWA in a sin­gle room*. To make the ac­cel­er­a­tor com­pact, the DWA needs to have a very high ac­cel­er­at­ing gra­di­ent. Also, beam trans­port in the DWA should be done with as few ex­ter­nal lens­es as pos­si­ble. We have de­vel­oped a trans­port scheme to trans­port the pro­ton bunch in the DWA and to focus the charge bunch on the pa­tient with­out using any ex­ter­nal fo­cus­ing lens­es. The trans­port scheme would allow us change the pro­ton beam spot size on the pa­tient eas­i­ly and rapid­ly. Re­sults of sim­u­la­tions using 3-D, EM PIC code, LSP** will be pre­sent­ed.
* G. J. Caporaso, Y-J Chen and S. E. Sampayan, Rev. of Accelerator Science and Technology, vol. 2, p. 253 (2009).
** Alliant Techsystems Inc., http://www.lspsuite.com/.
 
 
THPS087 Engineering Prototype for a Compact Medical Dielectric Wall Accelerator 3636
 
  • A. Zografos, T. Brown, A. Hening, V. Joshkin, K. Leung, Y.K. Parker, H.T. Pearce-Percy, D. Pearson, M. Rougieri, J. Weir
    CPAC, Livermore, CA, USA
  • R. Becker
    SSS, Gelnhausen, Germany
  • D.T. Blackfield, G.J. Caporaso, Y.-J. Chen, S. Falabella, G. Guethlein, S.A. Hawkins, S.D. Nelson, B. R. Poole, J.A. Watson
    LLNL, Livermore, California, USA
  • R.W. Hamm
    R&M Technical Enterprises, Pleasanton, California, USA
 
  Funding: Prepared by LLNL under Contract DE-AC52-07NA27344.
The Com­pact Par­ti­cle Ac­cel­er­a­tor Cor­po­ra­tion has de­vel­oped an ar­chi­tec­ture to pro­duce pulsed pro­ton bunch­es that will be suit­able for pro­ton treat­ment of can­cers. Sub­sys­tems in­clude a RFQ in­jec­tion sys­tem with a pulsed kick­er to se­lect the de­sired pro­ton bunch­es and a lin­ear ac­cel­er­a­tor in­cor­po­rat­ing a High Gra­di­ent In­su­la­tor with stacked Blum­leins to pro­duce the re­quired volt­age. The Blum­leins are switched with solid state laser driv­en op­ti­cal switch­es that are an in­te­gral part of the Blum­lein as­sem­blies. Other sub­sys­tems in­clude a laser, a fiber optic dis­tri­bu­tion sys­tem, an elec­tri­cal charg­ing sys­tem and beam di­ag­nos­tics. An en­gi­neer­ing pro­to­type has been con­struct­ed and it has been fully char­ac­ter­ized. Re­sults ob­tained from the en­gi­neer­ing pro­to­type sup­port the de­vel­op­ment of an ex­treme­ly com­pact 150 MeV sys­tem ca­pa­ble of mod­u­lat­ing en­er­gy, beam cur­rent and spot size on a shot to shot basis with­in the next two years. The paper will de­tail the con­struc­tion of the en­gi­neer­ing pro­to­type and dis­cuss ex­per­i­men­tal re­sults. In ad­di­tion, fu­ture de­vel­op­ment mile­stones and com­mer­cial­iza­tion plans will also be dis­cussed.