Title :
Time-Dependent Simulation of Free-Electron Lasers
Author_Institution :
Sci. Applications Int. Corp., McLean, VA
Abstract :
Time-dependent FEL simulations use a variety of techniques. Particle-in-cell codes have been used to simulate free-electron masers as stated in T. J. T. Kwan et al. (1977) and A. T. Lin et al. (1983); however, this is not feasible at short wavelengths. Most simulations use a slowly varying envelope approximation (SVEA). One such technique assumes that the envelope varies only in z combined with a field representation as an ensemble of discrete harmonics, which is equivalent to a time-dependent simulation, based in N. Piovella (1999) but is computationally prohibitive. A second technique uses an SVEA in both in z and t according to R. Bonifacio et al. (1989). The particles and fields are advanced in z using the same process as in steady-state simulations and then the time derivative describing slippage is applied. This is used in wiggler-averaged codes such as PROMETEO based in W. Fawley (1995) in 1-D and GINGER based in S. Reiche (1999) and GENESIS based in H. P. Freund (2000) in 3D. We describe the inclusion of this technique in the non-wiggler-averaged code MEDUSA, which is applied to amplifiers and oscillators
Keywords :
amplifiers; digital simulation; free electron lasers; oscillators; GENESIS; GINGER; MEDUSA; PROMETEO; amplifiers; discrete harmonics; free-electron lasers; nonwiggler-averaged code; oscillators; particle-in-cell codes; slowly varying envelope approximation; steady-state simulations; time-dependent simulation; wiggler-averaged codes; Computational modeling; Free electron lasers; Laser theory; Manuals; Masers; Oscillators; Plasmas; Steady-state; Undulators;
Conference_Titel :
Vacuum Electronics Conference, 2006 held Jointly with 2006 IEEE International Vacuum Electron Sources., IEEE International
Conference_Location :
Monterey, CA
Print_ISBN :
1-4244-0108-9
DOI :
10.1109/IVELEC.2006.1666294
