Experimental studies of overmoded relativistic backward-wave oscillators

• Published in: IEEE transactions on plasma science Vol. 26; no. 3; pp. 591 - 604
• Main Authors: Abe, D.K., Carmel, Y., Miller, S.M., Bromborsky, A., Levush, B., Antonsen, T.M., Destler, W.W.
• Format: Journal Article
• Language: English
• Published: New York IEEE 01.06.1998; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Electric breakdown; Electrodynamics; Electromagnetic fields; Electromagnetic scattering; Electromagnetism; Frequencies; Frequency; High power microwave generation; Internal stresses; Microwave devices; Microwave oscillators; Microwaves; Power generation; Radiation
• ISSN: 0093-3813; 1939-9375
• DOI: 10.1109/27.700796

Internal field-emission breakdown in the electrodynamic structures of high-power microwave (HPM) devices can seriously limit the device's output power and pulse duration. Increasing the diameter of the electrodynamic structure to several times an electromagnetic wavelength can reduce these internal fields to below critical breakdown levels, but may introduce mode competition as an unwanted side effect. This paper presents the design and results of experiments with overmoded (D//spl lambda//spl sim/3), sinusoidally corrugated backward-wave oscillators (BWOs) that successfully produced TM/sub 01//sup /spl odot//, high-power microwave radiation in the frequency range of 5.2-5.7 GHz. Overmoded BWOs reproducibly generated /spl sim/200 MW of peak power with corresponding efficiencies of /spl sim/4%. Pulse shortening was not observed in any of the experiments. The radiation generated by the devices was highly coherent (typically, /spl Delta/f/f<0.5%) and corresponded to a fundamental TM/sub 01//sup /spl odot//-mode interaction. The experimental results were compared with calculations made with recently developed nonlinear models; the measured data are shown to agree favorably with theory. The results of the experiments and modeling demonstrate that overmoded electrodynamic structures can be used to decrease internal electric field stresses while avoiding multimode generation and maintaining good spectral purity.