Numerical study on THz radiation of two-dimensional plasmon resonance of GaN HEMT array

doi:10.1088/1674-1056/acb0bb

中国物理B ›› 2023, Vol. 32 ›› Issue (4): 40701-040701.doi: 10.1088/1674-1056/acb0bb

Numerical study on THz radiation of two-dimensional plasmon resonance of GaN HEMT array

Hongyang Guo(郭宏阳), Ping Zhang(张平), Shengpeng Yang(杨生鹏), Shaomeng Wang(王少萌), and Yubin Gong(宫玉彬)^†

National Key Laboratory of Science and Technology on Vacuum Electronics, University of Electronic Science and Technology of China, Chengdu 610031, China

收稿日期:2022-11-04 修回日期:2022-12-26 接受日期:2023-01-06 出版日期:2023-03-10 发布日期:2023-03-30
通讯作者: Yubin Gong E-mail:ybgong@uestc.edu.cn
基金资助:
Project supported by the National Natural Science Foundation of China (Grant Nos. 92163204, 61921002, and 62171098).

Numerical study on THz radiation of two-dimensional plasmon resonance of GaN HEMT array

Hongyang Guo(郭宏阳), Ping Zhang(张平), Shengpeng Yang(杨生鹏), Shaomeng Wang(王少萌), and Yubin Gong(宫玉彬)^†

National Key Laboratory of Science and Technology on Vacuum Electronics, University of Electronic Science and Technology of China, Chengdu 610031, China

Received:2022-11-04 Revised:2022-12-26 Accepted:2023-01-06 Online:2023-03-10 Published:2023-03-30
Contact: Yubin Gong E-mail:ybgong@uestc.edu.cn
Supported by:
Project supported by the National Natural Science Foundation of China (Grant Nos. 92163204, 61921002, and 62171098).

摘要/Abstract

摘要： The GaN high electron mobility transistor (HEMT) has been considered as a potential terahertz (THz) radiation source, yet the low radiation power level restricts their applications. The HEMT array is thought to improve the coupling efficiency between two-dimensional (2D) plasmons and THz radiation. In this work, we investigate the plasma oscillation, electromagnetic radiation, and the integration characteristics of GaN HEMT targeting at a high THz radiation power source. The quantitative radiation power and directivity are obtained for integrated GaN HEMT array with different array periods and element numbers. With the same initial plasma oscillation phase among the HEMT units, the radiation power of the two-element HEMT array can achieve 4 times as the single HEMT radiation power when the array period is shorter than 1/8 electromagnetic wavelength. In addition, the radiation power of the HEMT array varies almost linearly with the element number, the smaller array period can lead to the greater radiation power. It shows that increasing the array period could narrow the main radiated lobe width while weaken the radiation power. Increasing the element number can improve both the radiation directivity and power. We also synchronize the plasma wave phases in the HEMT array by adopting an external Gaussian plane wave with central frequency the same as the plasmon resonant frequency, which solves the problem of the radiation power reduction caused by the asynchronous plasma oscillation phases among the elements. The study of the radiation power amplification of the one-dimensional (1D) GaN HEMT array provides useful guidance for the research of compact high-power solid-state terahertz sources.

关键词: GaN HEMT array, two-dimensional (2D) plasmons, THz emission

Abstract: The GaN high electron mobility transistor (HEMT) has been considered as a potential terahertz (THz) radiation source, yet the low radiation power level restricts their applications. The HEMT array is thought to improve the coupling efficiency between two-dimensional (2D) plasmons and THz radiation. In this work, we investigate the plasma oscillation, electromagnetic radiation, and the integration characteristics of GaN HEMT targeting at a high THz radiation power source. The quantitative radiation power and directivity are obtained for integrated GaN HEMT array with different array periods and element numbers. With the same initial plasma oscillation phase among the HEMT units, the radiation power of the two-element HEMT array can achieve 4 times as the single HEMT radiation power when the array period is shorter than 1/8 electromagnetic wavelength. In addition, the radiation power of the HEMT array varies almost linearly with the element number, the smaller array period can lead to the greater radiation power. It shows that increasing the array period could narrow the main radiated lobe width while weaken the radiation power. Increasing the element number can improve both the radiation directivity and power. We also synchronize the plasma wave phases in the HEMT array by adopting an external Gaussian plane wave with central frequency the same as the plasmon resonant frequency, which solves the problem of the radiation power reduction caused by the asynchronous plasma oscillation phases among the elements. The study of the radiation power amplification of the one-dimensional (1D) GaN HEMT array provides useful guidance for the research of compact high-power solid-state terahertz sources.

Key words: GaN HEMT array, two-dimensional (2D) plasmons, THz emission

中图分类号: (Infrared, submillimeter wave, microwave, and radiowave sources)

07.57.Hm

42.72.Ai (Infrared sources)

Hongyang Guo(郭宏阳), Ping Zhang(张平), Shengpeng Yang(杨生鹏), Shaomeng Wang(王少萌), and Yubin Gong(宫玉彬). Numerical study on THz radiation of two-dimensional plasmon resonance of GaN HEMT array[J]. 中国物理B, 2023, 32(4): 40701-040701.

参考文献

[1] Siegel P H 2002 IEEE T. Microw. Theory 50 910
[2] Liu S 2006 China Basic Science 7 (in Chinese)
[3] Dhillon S S, Vitiello M S, Linfield E H, et al. 2017 J. Phys. D 50 043001
[4] Tonouchi M 2007 Nat. Photon. 1 97
[5] Lewis R A 2014 J. Phys. D 47 374001
[6] Allen S J, Tsui D C and Logan R A 1977 Phys. Rev. Lett. 38 980
[7] Gornik E and Tsui D C 1976 Phys. Rev. Lett. 37 1425
[8] Shur M S 2021 IEEE Sens. J. 21 12752
[9] Otsuji T and Shur M 2014 IEEE Microw. Mag. 15 43
[10] Dyakonov M and Shur M 1993 Phys. Rev. Lett. 71 2465
[11] Knap W, Lusakowski J, Parenty T, et al. 2004 Appl. Phys. Lett. 84 2331
[12] Lusakowski J, Knap W, Dyakonova N, et al. 2005 J. Appl. Phys. 97 064307
[13] Boubanga-Tombet S, Teppe F, Torres J, et al. 2010 Appl. Phys. Lett. 97 262108
[14] Zhou Y, Li X, Tan R, et al. 2013 J. Semicond. 34 022002
[15] Jakštas V, Grigelionis I, Janonis V, et al. 2017 Appl. Phys. Lett. 110 202101
[16] Shalygin V, Moldavskaya M, Vinnichenko M, et al. 2019 J. Appl. Phys. 126 183104
[17] Meziani Y M, Otsuji T, Hanabe M, et al. 2007 Appl. Phys. Lett. 90 061105
[18] Meziani Y M, Handa H, Knap W, et al. 2008 Appl. Phys. Lett. 92 201108
[19] Watanabe T, Satou A, Suemitsu T, et al. 2013 CLEO: 2013, June 9-14, 2013, San Jose, California, pp. 1-2
[20] Hosotani T, Satou A and Otsuji T 2021 Appl. Phys. Express 14 051001
[21] Aizin G R, Mikalopas J and Shur M 2016 Phys. Rev. B 93 195315
[22] Shur M and Gaska R (US patent) 7638817 B2 [2009-10-29]
[23] Elkhatib T A, Kachorovskii V Y, Stillman W J, et al. 2010 IEEE Trans. Microw Theor. Tech. 58 331
[24] Popov V V, Tsymbalov G M, Fateev D V, et al. 2006 Appl. Phys. Lett. 89 123504
[25] Bhardwaj S, Nahar N K, Rajan S, et al. 2016 IEEE Trans. Electron. Dev. 63 990
[26] Nafari M, Aizin G R and Jornet J M 2018 Phys. Rev. Appl. 10 064025
[27] Ardaravičius L, Matulionis A, Liberis J, et al. 2003 Appl. Phys. Lett. 83 4038
[28] Dmitriev A P, Furman A S and Kachorovskii V Y 1996 Phys. Rev. B 54 14020
[29] Dyakonov M and Shur M S 2005 Appl. Phys. Lett. 87 111501
[30] Zhang Y and Shur M S 2020 IEEE Trans. Electron. Dev. 67 4858
[31] Balanis C A 2005 Antenna Theory Analysis and Design, 4th edn. (Hoboken, New Jersey.: John Wiley & Sons, Inc.) pp. 285-384

Numerical study on THz radiation of two-dimensional plasmon resonance of GaN HEMT array

Numerical study on THz radiation of two-dimensional plasmon resonance of GaN HEMT array

RichHTML

PDF (PC)

赞

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

Metrics

本文评价

推荐阅读 0

[1]	Ben Fu(付犇), Shi-Xing Yu(余世星), Na Kou(寇娜), Zhao Ding(丁召), and Zheng-Ping Zhang(张正平). Design of cylindrical conformal transmitted metasurface for orbital angular momentum vortex wave generation[J]. 中国物理B, 2022, 31(4): 40703-040703.
[2]	Jing Shu(舒靖), Ping Zhang(张平), Man Liang(梁满), Sheng-Peng Yang(杨生鹏), Shao-Meng Wang(王少萌), and Yu-Bin Gong(宫玉彬). Smith-Purcell radiation improved by multi-grating structure[J]. 中国物理B, 2022, 31(4): 44103-044103.
[3]	Huali Zhu(朱华利), Yong Zhang(张勇), Kun Qu(屈坤), Haomiao Wei(魏浩淼), Yukun Li(黎雨坤), Yuehang Xu(徐跃杭), and Ruimin Xu(徐锐敏). A terahertz on-chip InP-based power combiner designed using coupled-grounded coplanar waveguide lines[J]. 中国物理B, 2021, 30(12): 120701-120701.
[4]	Jia-Hui Wang(王佳慧), Guo-Yang Wang(王国阳), Xin Liu(刘欣), Si-Yu Shao(邵思雨), Hai-Yun Huang(黄海云), Chen-Xin Ding(丁晨鑫), Bo Su(苏波), and Cun-Lin Zhang(张存林). Effect of external electric field on the terahertz transmission characteristics of electrolyte solutions[J]. 中国物理B, 2021, 30(11): 110204-110204.
[5]	马媛媛, 黄昊翀, 郝思博, 汤伟冲, 郑志远, 张自力. Investigation of copper sulfate pentahydrate dehydration by terahertz time-domain spectroscopy[J]. 中国物理B, 2019, 28(6): 60702-060702.
[6]	李铮迪, 杜朝海, 戚向波, 罗里, 刘濮鲲. A 0.33-THz second-harmonic frequency-tunable gyrotron[J]. 中国物理B, 2016, 25(2): 29401-029401.
[7]	谢辉, 赵有文, 刘彤, 董志远, 杨俊, 刘京明. C–H complex defects and their influence in ZnO single crystal[J]. 中国物理B, 2015, 24(10): 107704-107704.
[8]	蔡金赤, 胡林林, 马国武, 陈洪斌, 金晓, 陈怀璧. Theoretical models for designing a 220-GHz folded waveguide backward wave oscillator[J]. 中国物理B, 2015, 24(6): 60701-060701.
[9]	于淼, 徐念喜, 高劲松. Infrared transparent frequency selective surface based on iterative metallic meshes[J]. , 2015, 24(3): 30701-030701.
[10]	刘鲁伟, 魏彦玉, 王少萌, 侯艳, 殷海荣, 赵国庆, 段兆云, 徐进, 宫玉彬, 王文祥, 杨明华. A novel slotted helix slow-wave structure for high power Ka-band traveling-wave tubes[J]. 中国物理B, 2013, 22(10): 108401-108401.
[11]	刘洋, 徐进, 赖剑强, 许雄, 沈飞, 魏彦玉, 黄民智, 唐涛, 宫玉彬 . Design of a reentrant double staggered ladder circuit for V-band coupled-cavity traveling-wave tube[J]. 中国物理B, 2012, 21(7): 74202-074202.
[12]	沈飞, 魏彦玉, 许雄, 殷海荣, 宫玉彬, 王文祥. Study on a W-band modified V-shaped microstrip meander-line traveling-wave tube[J]. 中国物理B, 2012, 21(6): 64210-064210.
[13]	许雄, 魏彦玉, 沈飞, 黄民智, 唐涛, 段兆云, 宫玉彬. Research of sine waveguide slow-wave structure for a 220-GHz backward wave oscillator[J]. 中国物理B, 2012, 21(6): 68402-068402.
[14]	史宗君, 唐效频, 杨梓强, 兰峰, 梁正. Simulations of a two-stream backward-wave oscillator with a slot-hole structure[J]. 中国物理B, 2012, 21(1): 18401-018401.
[15]	黄杰, 董军荣, 杨浩, 张海英, 田超, 郭天义. A k-band broadband monolithic distributed frequency multiplier based on nonlinear transmission line[J]. 中国物理B, 2011, 20(6): 60702-060702.