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Lau, W.K.

Paper Title Page
MOPEA074 Resonant Transition Radiation Induced by an Ultrashort Electron Bunch from Aluminium Foil Stack 244
 
  • W.C. Cheng
    National Chiao Tung University, Hsinchu
  • N.Y. Huang
    NTHU, Hsinchu
  • W.K. Lau
    NSRRC, Hsinchu
 
 

Resonant transition radiation (RTR) driven by a femtosecond electron beam is being studied. An aluminum foil stack with vacuum spacers is used as the radiator. With a 27 MeV electron bunch with pulse duration at ~ 100 fsec incident normally on the aluminum foil stack, high photon yields in hard X-ray regime can be obtained. Characteristics of the radiation such as emission spectrum, spatial distribution are calculated. The dependence of RTR photon yields on beam size and bunch length are also studied.

 
TUPEA015 Focusing of Ultrashort Electron Bunch for Femtosecond Inverse Compton Scattering X-Ray Source 1357
 
  • N.Y. Huang, S.S. Yang
    NTHU, Hsinchu
  • H. Hama
    Tohoku University, School of Scinece, Sendai
  • W.K. Lau
    NSRRC, Hsinchu
 
 

Design of an intense but tightly focused ultrashort electron beam for production of sub-hundred femtosecond x-ray pulses that based on head-on inverse Compton scattering (ICS) has been studied. The three dimensional (3D) space charge dynamics has been tracked and optimized throughout the whole beamline. It is found that the focusing ultrashort electron pulses as short as 67 fs can be produced by compressing the energy-chirped beam from a thermionic cathode rf gun with an alpha magnet and linac operating at injection phase near zero crossing. This multi-bunch electron beam has an intensity of 30 pC per bunch and is accelerated to 27 MeV with an S-band linac structure. The compressed electron beam is focused to 64 μm for scattering with an 800 nm, 3.75 mJ laser in the laser-beam interaction chamber. With this method, total peak flux of back-scattered x-ray photons exceeds 1018 photons/sec is achievable with the shortest wavelength of 0.7 Å.

 
TUPE043 THz-pulse-train photoinjector 2236
 
  • C.H. Chen, K.Y. Huang, Y.-C. Huang
    NTHU, Hsinchu
  • W.K. Lau, A.P. Lee
    NSRRC, Hsinchu
 
 

A THz-pulse-train photoinjector is under construction at the High-energy OPtics and Electronics (HOPE) Lab. at National Tsinghua University, Taiwan. This photoinjector is believed to be useful for generating high-power THz radiation, as well as for driving or loading a plasma-wave accelerator. A THz laser beat wave with full tunability in its beat frequency is employed to induce the emission of the THz electron pulses from the photoinjector. We show in our study that such a photoinjector is capable of generating periodically bunched MeV electrons with a bunching factor larger than 0.1 at THz frequencies for a total amount of 1nC charges in a 10-ps time duration. We will also present a driver laser technology that can tune the electron bunch frequency with ease and help the growth of the high harmonics in the bunching spectrum of accelerated electrons. Experimental progress on this photoinjector will be reported in the conference. The authors gratefully acknowledge funding supports from National Scienc Council under Contract NSC 97-2112-M-007-018 -MY2, National Synchrotron Radiation Research Center under Project 955LRF01N, and National Tsinghua University under Project 98N2534·101.

 
THPD013 Construction of a Thermionic RF Gun Linac System for Ultrashort Electron Beam 4304
 
  • W.K. Lau, J.H. Chen, J.-Y. Hwang, A.P. Lee, C.C. Liang, T.H. Wu
    NSRRC, Hsinchu
  • W.C. Cheng
    National Chiao Tung University, Hsinchu
  • N.Y. Huang
    NTHU, Hsinchu
 
 

A 25-30 MeV S-band linac system that equipped with thermionic cathode rf gun is being constructed at NSRRC for generation of ultrashort relativistitic electron beam. According to simulation studies, high quality GHz repetition rate electron pulses of about 50 pC as short as few tens fsec can be produced. This injector system will be used as the driver for experiments on fsec head-on inverse Compton scattering X-ray source and high power wake field microwave sources. The progress of our construction work will be presented.