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Research on a Ka-band large-orbit gyro-TWT with periodic dielectric-loaded structure
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  • Jintao Yang,
  • Efeng Wang,
  • Chaojun Lei,
  • Qixiang Zhao,
  • Jinjun Feng,
  • Zihan Lei,
  • Xu Zeng
Jintao Yang
Beijing Vacuum Electronics Research Institute

Corresponding Author:[email protected]

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Efeng Wang
Beijing Vacuum Electronics Research Institute
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Chaojun Lei
China People's Police University
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Qixiang Zhao
Guilin University of Electronic Technology
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Jinjun Feng
National Key Laboratory of Science and Technology on Vacuum Electronics
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Zihan Lei
Beijing Vacuum Electronics Research institute
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Xu Zeng
Beijing Vacuum Electronics Research institute
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Abstract

This paper presents a design of a gyro-TWT operating in the large-orbit electron beam mode, with the aim of reducing the working magnetic field while ensuring operational efficiency. The periodic dielectric-loaded structure is adopted as the high-frequency interaction circuit, which has not been reported in the application of large-orbit gyro-TWT in literature, while this structure has been successfully applied in the development of small-orbit devices. This paper conducts a comprehensive study and analysis of this structure and achieves stable operation in the Ka-band after the optimization of the tube. This tube works at second harmonic of electron frequency in the mode of large-orbit electron beam. The required magnetic field is only 5100 Gauss, which can be generated using electromagnetic coils instead of superconducting magnets. The operational parameters include voltage of 75 kV, current of 9A, and velocity spread of 3.5%. Under these conditions, the device presents stable operation, with -3 dB bandwidth of 4.3 GHz, and maximum output power of 165 kW. This result meets the expected requirements for magnetic field and operational efficiency, thus validating the feasibility of practical fabrication of large-orbit gyro-TWT with periodic dielectric-loaded structure.
12 Nov 2023Submitted to Electronics Letters
14 Nov 2023Submission Checks Completed
14 Nov 2023Assigned to Editor
15 Nov 2023Reviewer(s) Assigned
19 Nov 2023Review(s) Completed, Editorial Evaluation Pending
22 Nov 2023Editorial Decision: Revise Major