Abstract
The operation features of the coaxial virtual cathode oscillator emitting electrons in the outer radial direction were investigated through simulations and experiments. A coaxial vircator was compared with an axial vircator when the anode to cathode distance of both vircators was 6 mm. The proposed coaxial vircator was operated when the anode to cathode distance was 5 mm, 6 mm, and 7 mm. The peak power and frequency of the microwave generated from the proposed coaxial vircator when the anode to cathode distance was 6 mm were 20.18 MW and 6.17 GHz, respectively. The simulations and experiments show that the proposed coaxial vircator generates 80% more microwave power than the axial vircator with the same anode to cathode distance. According to the simulations and experiments, the proposed coaxial vircator tends to generate a higher power average when the anode to cathode distance was larger than 5 mm. The frequency of the proposed coaxial vircator when the anode to cathode distance was 5 mm and 7 mm was approximately 8 GHz and 5 GHz, respectively. The geometric factor of the proposed coaxial vircator was considered to be the reason for the greater microwave power generation than the axial vircator. The frequency of the proposed coaxial vircator decreases inversely proportional with the anode to cathode distance as observed in the axial and basic coaxial vircators.
Highlights
High-power microwave (HPM) devices have been investigated experimentally and numerically for use in many industrial and academic fields [1]
The proposed coaxial vircator tends to be sharper near the dominant frequencies than the axial vircator
The experimental results on the vircators with the same anode to cathode distance show that the microwave power enhancement was 80%, which is in accordance with the simulation expectations
Summary
High-power microwave (HPM) devices have been investigated experimentally and numerically for use in many industrial and academic fields [1]. The HPM sources have different microwave generation mechanisms, the devices were studied to modulate their microwave frequency and mode to generate microwaves with higher power and higher efficiencies. The vircator can be driven without external magnetic field generating devices These allow the vircator to have simple operation features, simple structure, compactness, and facile high-voltage operation. A vircator is widely investigated in academic fields to improve its low efficiencies and modulate its output frequency by installing additional structures and changing the cathode and anode materials [8,9,10,11,12,13,14,15,16]. The microwave power and frequency of the coaxial vircator were investigated by comparing with the power and frequency of the axial vircator with the same anode to cathode distance
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