Title :
The Michelson resonator free-electron laser. I. Passive mode structure and mode decay
Author :
Szarmes, Eric B. ; Madey, John M.J.
Author_Institution :
Dept. of Phys., Duke Univ., Durham, NC, USA
fDate :
2/1/1993 12:00:00 AM
Abstract :
A general analysis of the evolution of phase locking in an RF linac-driven Michelson resonator free-electron laser (FEL) is presented. By providing a delay of one RF period in the secondary arm of the interferometer, successive optical pulses can be coupled at the beamsplitter, so that they build up from noise with a definite phase relationship. Phase locking is described in terms of longitudinal mode decay by extracting the mode losses directly from the passive frequency response of the resonator. The analyses predict significant mode structure simplification in microsecond macropulses, so that high-resolution spectroscopy is feasible on RF linac-driven FELs. Simulations of the perfectly tuned Michelson resonator FEL are described from spontaneous radiation to saturation, using a one-dimensional pulse propagation code. Excellent agreement with the analytical results in the small-signal regime is demonstrated
Keywords :
free electron lasers; laser cavity resonators; laser mode locking; laser modes; laser theory; light interferometers; optical losses; Michelson resonator free-electron laser; RF linac driven FEL; RF period delay; beamsplitter; high-resolution spectroscopy; interferometer; longitudinal mode decay; microsecond macropulses; mode decay; mode losses; noise; one-dimensional pulse propagation code; optical pulses; passive frequency response; passive mode structure; phase locking; saturation; small-signal regime; spontaneous radiation; Delay; Free electron lasers; Laser mode locking; Laser modes; Laser noise; Optical coupling; Optical interferometry; Optical pulses; Optical resonators; Radio frequency;
Journal_Title :
Quantum Electronics, IEEE Journal of
