Modern methods of acceleration and compact light sources

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High-Intensity Compact X-ray Source technology Present status Target Key points Electron source 300 nC/pulse 10,000nC/pulse (2008-2009) 48,000 nC/pulse (2010-2012) Pulse laser, new photocathode, 1 msec pulse length SC Cavity Pulsed laser storage Pulse: 25 MV/m CW: 12 MV/m Pulse: 30 MV/m CW: 20 MV/m Non-defect and clean surface, Precise electron beam welding, High precision forming, Noncontamination material 0.5 mJ/pulse, Waist: 30 µm 50 mJ/pulse, Waist: 8 µm 4-mirror optical cavity Colliding control µm beam orbit control Sub- µm beam orbit control minimizing environmental effect, Fast feedback control A. Seryi, 9 th Nov 2010 J. Urakawa, et al, Quantum Beam Project
Quantum beam Organization & Responsibility Compact and reliable Multi-beam Klystron R&D Committee for project evaluation High powwer RF Toshiba Compact Klystron Hiroshima U. Laser storage RF Gun Photo-cathode Main Institute KEK SC RF Accelerator development High stablle HV PS Hitachi DC High Voltage Source System design, Operation, Performance High stablle HV PS Measurement Education for young sientists Pullsed Laser Storage ATF, STF JAEA DC High Voltage PS High Quality and Intensity e- sourcePhoto-Cathode ERL Electron Source Device Waseda U. X-ray detector Laser Compton Exp. Compact Accelerator U. of Tokyo Photo-cathode Input coupler A. Seryi, 9 th Nov 2010 J. Urakawa, et al, Quantum Beam Project
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Modern methods of acceleration and compact light sources

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