Modern methods of acceleration and compact light sources

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Compact coherent Compton EUV source Extreme ultra-violet (EUV) lithography at λ=13.5nm – strongest candidate of the next generation processing of Large Scale Integration circuits FEL schemes are possible, but require ~GeV scale facilities Compact EUV source based on a laser Compton scattering between a 7 MeV micro-bunched electron beam and a high-intensity CO2 laser pulse Severe condition for the average current and the optical undulator length may be eased by use of coherent effect, when the pre-bunched beam is applied to the laser Compton scheme S. Kashiwagi et al. / Radiation Physics and Chemistry 78 (2009) 1112–1115 A. Seryi, 9 th Nov 2010
Compton X-ray source at Univ. of Tokyo X-rays 10–40 keV for medical science, biology, and materials science Multi-bunch electron beam and a longpulse laser for higher flux Electron beam: 200 mA peak & 2 mA average under 10 Hz operation, multi-bunch (10 4 bunches in 1 ms) Laser: energy 1.4 J, duration 10 ns at a wavelength of 532 nm. 30 MeV X-band (11.424 GHz) linac 3.5-cell thermionic cathode RF-gun Have demonstrated the 2MeV electron beam generation from the RF-gun F. Sakamoto et al, Nuclear Instruments and Methods in Physics Research A 608 (2009) S36–S40 A. Seryi, 9 th Nov 2010
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Modern methods of acceleration and compact light sources

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