Stacked dual beam electron optical system for THz integrated wideband traveling wave tube
In this paper, a stacked dual beam electron gun and the associated electron optical system are proposed. The stacked dual beam electron gun includes two compact focusing electrodes which help to achieve dual sheet beams. As an application of this dual beam electron gun, a 340 GHz integrated dual bea...
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sg-ntu-dr.10356-874502020-03-07T13:57:30Z Stacked dual beam electron optical system for THz integrated wideband traveling wave tube Shao, Wei Xu, Duo Wang, Zhanliang Gong, Huarong Lu, Zhigang Duan, Zhaoyun Wei, Yanyu Gong, Yubin Aditya, Sheel School of Electrical and Electronic Engineering Satellite Research Centre Slow Wave Structure Vacuum Tubes Engineering::Electrical and electronic engineering In this paper, a stacked dual beam electron gun and the associated electron optical system are proposed. The stacked dual beam electron gun includes two compact focusing electrodes which help to achieve dual sheet beams. As an application of this dual beam electron gun, a 340 GHz integrated dual beam traveling wave tube (TWT) based on the staggered dual vane slow-wave structure (SWS) is also put forward. In order to reduce the length of the TWT, a novel input/output coupler is introduced. The overall transmission characteristics of the SWS structure together with the input/output couplers show a wide bandwidth covering a frequency range of 306 GHz to 360 GHz. Based on the parameters obtained for the integrated TWT, a stacked dual-beam electron gun with dual focusing electrodes is designed to achieve a beam current of 43 mA, a beam voltage of 21.4 kV, and a cross-sectional size of each beam of 0.3 mm × 0.08 mm. A uniform magnetic field of 0.52 T is utilized to focus the dual electron beams, and a beam transmission efficiency of 97.1% is achieved over a length of 50 mm. Finally, particle in cell simulation results show that the integrated dual-beam TWT can generate an output power of 5 W over the frequency range of 315 GHz to 350 GHz, with the maximum output power of 24.5 W at 330 GHz. Published version 2019-07-11T08:03:56Z 2019-12-06T16:42:09Z 2019-07-11T08:03:56Z 2019-12-06T16:42:09Z 2019 Journal Article Shao, W., Xu, D., Wang, Z., Gong, H., Lu, Z., Duan, Z., . . . Aditya, S. (2019). Stacked dual beam electron optical system for THz integrated wideband traveling wave tube. Physics of Plasmas, 26(6), 063106-. doi:10.1063/1.5096331 1070-664X https://hdl.handle.net/10356/87450 http://hdl.handle.net/10220/49299 10.1063/1.5096331 en Physics of Plasmas © 2019 The Author(s). All rights reserved. This paper was published by AIP in Physics of Plasmas and is made available with permission of The Author(s). 9 p. application/pdf |
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Slow Wave Structure Vacuum Tubes Engineering::Electrical and electronic engineering |
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Slow Wave Structure Vacuum Tubes Engineering::Electrical and electronic engineering Shao, Wei Xu, Duo Wang, Zhanliang Gong, Huarong Lu, Zhigang Duan, Zhaoyun Wei, Yanyu Gong, Yubin Aditya, Sheel Stacked dual beam electron optical system for THz integrated wideband traveling wave tube |
| description |
In this paper, a stacked dual beam electron gun and the associated electron optical system are proposed. The stacked dual beam electron gun includes two compact focusing electrodes which help to achieve dual sheet beams. As an application of this dual beam electron gun, a 340 GHz integrated dual beam traveling wave tube (TWT) based on the staggered dual vane slow-wave structure (SWS) is also put forward. In order to reduce the length of the TWT, a novel input/output coupler is introduced. The overall transmission characteristics of the SWS structure together with the input/output couplers show a wide bandwidth covering a frequency range of 306 GHz to 360 GHz. Based on the parameters obtained for the integrated TWT, a stacked dual-beam electron gun with dual focusing electrodes is designed to achieve a beam current of 43 mA, a beam voltage of 21.4 kV, and a cross-sectional size of each beam of 0.3 mm × 0.08 mm. A uniform magnetic field of 0.52 T is utilized to focus the dual electron beams, and a beam transmission efficiency of 97.1% is achieved over a length of 50 mm. Finally, particle in cell simulation results show that the integrated dual-beam TWT can generate an output power of 5 W over the frequency range of 315 GHz to 350 GHz, with the maximum output power of 24.5 W at 330 GHz. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Shao, Wei Xu, Duo Wang, Zhanliang Gong, Huarong Lu, Zhigang Duan, Zhaoyun Wei, Yanyu Gong, Yubin Aditya, Sheel |
| format |
Article |
| author |
Shao, Wei Xu, Duo Wang, Zhanliang Gong, Huarong Lu, Zhigang Duan, Zhaoyun Wei, Yanyu Gong, Yubin Aditya, Sheel |
| author_sort |
Shao, Wei |
| title |
Stacked dual beam electron optical system for THz integrated wideband traveling wave tube |
| title_short |
Stacked dual beam electron optical system for THz integrated wideband traveling wave tube |
| title_full |
Stacked dual beam electron optical system for THz integrated wideband traveling wave tube |
| title_fullStr |
Stacked dual beam electron optical system for THz integrated wideband traveling wave tube |
| title_full_unstemmed |
Stacked dual beam electron optical system for THz integrated wideband traveling wave tube |
| title_sort |
stacked dual beam electron optical system for thz integrated wideband traveling wave tube |
| publishDate |
2019 |
| url |
https://hdl.handle.net/10356/87450 http://hdl.handle.net/10220/49299 |
| _version_ |
1681049331394674688 |