Time- and frequency-domain models for Smith-Purcell radiation from a two-dimensional charge moving above a finite length grating

Amit S. Kesar, Mark Hess, Stephen E. Korbly, Richard J. Temkin
2005 Physical Review E  
Smith-Purcell radiation ͑SPR͒, formed by an electron beam traveling above a grating, is a very promising source of coherent radiation from the THz to the optical regime. We present two theoretical calculations of the SPR from a two-dimensional bunch of relativistic electrons passing above a grating of finite length. The first calculation uses the finite-difference time-domain approach with the total-field/scattered-field procedure for fields incident on the grating. This calculation allows good
more » ... physical insight into the radiation process and also allows arbitrary geometries to be treated. The second calculation uses an electric-field integral equation method. Good agreement is obtained between these two calculations. The results of these theoretical calculations are then compared with a theoretical formalism based on an infinite-length grating. The latter formalism allows periodic boundary conditions to be rigorously applied. For gratings with less than ϳ50 periods, a significant error in the strength of the radiated field is introduced by the infinite-grating approximation. It is shown that this error disappears asymptotically as the number of periods increases. The Wood-Rayleigh anomalies, predicted in the infinite-grating approximation, were not seen in our finite-grating calculations. The SPR resonance condition is the same in all three formalisms. Numerical examples are presented for an ϳ18 MeV, 50 nC/ m, 200 µm bunch traveling 0.6 mm above a ten-period echelle grating having a 2.1-mm periodicity.
doi:10.1103/physreve.71.016501 pmid:15697740 fatcat:late653pwrhd3bixl2us2cttxm