0.85 THz可调谐式折叠波导再生反馈真空电子学振荡器的理论及实验研究

李天一; 潘攀; 孟维思; 李栋; 蔡军; 邬显平; 冯进军; 闫铁昌

doi:doi:10.11972/j.issn.1001-9014.2020.03.003

红外与毫米波学报, 2020, 39 (3): 284, 网络出版: 2020-07-07

0.85 THz可调谐式折叠波导再生反馈真空电子学振荡器的理论及实验研究

Theoretical and experimental study of a 0.85-THz tunable folded waveguide regenerative-feedback vacuum-electronics oscillator

李天一潘攀孟维思李栋蔡军邬显平冯进军闫铁昌

作者单位

National Key Laboratory of Science and Technology on Vacuum Electronics, Beijing Vacuum Electronics Research Institute, Beijing0005, China

引用该论文

李天一, 潘攀, 孟维思, 李栋, 蔡军, 邬显平, 冯进军, 闫铁昌. 0.85 THz可调谐式折叠波导再生反馈真空电子学振荡器的理论及实验研究[J]. 红外与毫米波学报, 2020, 39(3): 284.

Tian-Yi LI, Pan PAN, Wei-Si MENG, Dong LI, Jun CAI, Xian-Ping WU, Jin-Jun FENG, Tie-Chang YAN. Theoretical and experimental study of a 0.85-THz tunable folded waveguide regenerative-feedback vacuum-electronics oscillator[J]. Journal of Infrared and Millimeter Waves, 2020, 39(3): 284.

参考文献

[1] Folded Waveguide Traveling-Wave Tube Sources for Terahertz Radiation[J].IEEE Trans. on Plasma Science, Vol. 32, No. 3, June 2004.

[2] TucekJ., KreischerK., Gallagher and RD.. Vogel, Development and Operation of a 650GHz Folded Waveguide Source[C], IVEC2007, Kytakushu, Japan, 2007：219-220

[3] CaiJun, FengJinjun, HuYinfu, et al. Investigation of THz Regenerative Oscillator[C]. Proceeding of 2010 International Vacuum Electronics Conference, 2010:323

[4] GaoPeng. Study on Traveling Wave Tube Regenerative Feedback Oscillators[R].University of Electronic Science and Technology of China.2010

[5] ZhuJ F , DuC H , BaoL Y , et al. A High Harmonic Terahertz Frequency Multiplier Based on Plasmonic Grating[C]. 2018 43rd International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz2018. 2018.

[6] LiuShenggang. Introduction to microwave electronics[M]. University of Electronic Science and Technology of China. Chengdu1983:349-364.

[7] CaiJun. Study on W-band folded Waveguide Slow Wave Structure[R].Shandong University.2006

[8] IvesLawrence, KoryCarol, RoadMike, et al.MEMS-Based TWT Development[C].IVEC2003,Seoul, Korea,2003:64-65.

[9] RoweJ. E.. Nonlinear electron-wave interaction phenomenon[M]. Academic Press, Inc., NewYork,1965,50-180

[10] HammerstadE,JensenO. Accurate models for microstrip computer-aided design[C]. IEEE MTT-S International Microwave Symposium Digest. Washington,DC,USA:IEEE, 1980:28-30.

[11] MalekabadiA , PaoloniC . UV-LIGA microfabrication process for sub-terahertz waveguides utilizing multiple layered SU-8 photoresist[J]. Journal of Micromechanics and Microengineering, 2016, 26(9):095010.

[12] LiTianyi， MengWeisi， PanPan，et al.Study of 0.8 THz regenerative feedback oscillators[J].HIGH POWER LASER AND PARTICLE BEAMS.(李天一,孟维思,潘攀,等.0.8THz再生反馈振荡器的仿真模拟研究.强激光与粒子束）,2019,31(12):39-43

李天一, 潘攀, 孟维思, 李栋, 蔡军, 邬显平, 冯进军, 闫铁昌. 0.85 THz可调谐式折叠波导再生反馈真空电子学振荡器的理论及实验研究[J]. 红外与毫米波学报, 2020, 39(3): 284. Tian-Yi LI, Pan PAN, Wei-Si MENG, Dong LI, Jun CAI, Xian-Ping WU, Jin-Jun FENG, Tie-Chang YAN. Theoretical and experimental study of a 0.85-THz tunable folded waveguide regenerative-feedback vacuum-electronics oscillator[J]. Journal of Infrared and Millimeter Waves, 2020, 39(3): 284.

0.85 THz可调谐式折叠波导再生反馈真空电子学振荡器的理论及实验研究

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