Litcius/Paper detail

Experimental Investigation of a Shape-Optimized Staggered Double-Vane Slow-Wave Structure for Terahertz Traveling-Wave Tubes

Shengkun Jiang, Guang Yang, Zhanliang Wang, Xin Wang, Xuanming Zhang, Zhifang Lyu, Tao Tang, Huarong Gong, Yubin Gong, Zhaoyun Duan

2022IEEE Transactions on Electron Devices31 citationsDOI

Abstract

Enormous concerns focus on the high-power and wide bandwidth traveling-wave tube (TWT) for its outstanding performance. In this article, a shape-optimized staggered double-vane slow-wave structure (SWS) for terahertz (THz) sheet beam TWT is proposed. The shape-optimized staggered double-vane SWS takes the advantages of higher interaction impedance, lower transmission loss, and lower phase velocity than conventional staggered double-vane SWSs. The shape-optimized staggered double-vane SWS with 85 periods is designed, fabricated, and cold tested. The measured transmission loss of the shape-optimized staggered double-vane SWS is less than 0.79 dB/cm in the frequency range of 0.211–0.26 THz, which is in good agreement with the simulation results. Furthermore, the beam–wave interaction analysis of a sheet beam TWT with this SWS is given. The output power is predicted to be >100 W with 3-dB bandwidth of >50 GHz. The results show that the shape-optimized staggered double-vane SWS is a very promising scheme to construct a high-power and wideband THz TWT for future applications such as communication and imaging.

Topics & Concepts

Traveling-wave tubeTerahertz radiationBandwidth (computing)OpticsWidebandBeam (structure)Electrical impedancePhysicsPhase velocityMaterials scienceAcousticsTelecommunicationsEngineeringAmplifierQuantum mechanicsGyrotron and Vacuum Electronics ResearchMicrowave Engineering and Waveguides
Experimental Investigation of a Shape-Optimized Staggered Double-Vane Slow-Wave Structure for Terahertz Traveling-Wave Tubes | Litcius