PIC Simulations of a Novel Sub-1-GHz Compact Relativistic Cherenkov Oscillator Using Spiral Metamaterials With High Output Power

We developed a novel spiral metamaterial (MTM) unit cell and constructed a slow wave structure (SWS) based on it at sub-1-GHz frequency and developed a compact relativistic Cherenkov oscillator with high efficiency under relatively low guide magnetic field. Particle-in-cell (PIC) simulations demonstrate that a circular waveguide with radius ro1=4.01 cm loaded with a spiral MTM SWS can radiate the TM 01 mode with output power 1.06 GW and frequency 945 MHz using a pulsed electron beam with energy 700keV ( U = 700 kV) and current 2kA with a magnetic field B=0.58 T, and the corresponding beam-to-microwave power conversion efficiency is 75.6%. When the applied voltage is varied from 400 to 700 kV, the output frequency of the TM 01 mode is centered at 940 MHz with a beam-tuning frequency bandwidth of 10 MHz, while the output power can be greater than 600 MW. This work seeks to design a compact backward wave oscillator (BWO) for high power for sub-1-GHz generation across a wide voltage range and with low dispersion