基于InP/InGaAs肖特基二极管的高灵敏太赫兹探测器

High sensitivity terahertz detectors based on the InP/InGaAs Schottky Barrier Diodes

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摘要 InP/InGaAs肖特基二极管(SBDs)探测器因其高电子迁移率和低势垒材料特性,具有非常高的电压响应灵敏度,广泛用于高灵敏太赫兹波探测技术中。为进一步降低器件寄生效应,提升其高频性能,本文提出一种无衬底单台面T型结新型结构的肖特基器件,器件的截止频率为9.5THz。基于新型结构的InP/InGaAs肖特基器件技术,研制了220~330GHz、30~500GHz、400~600 GHz和500~750 GHz等多频段的太赫兹探测器模块。其中220~330 GHz频段太赫兹检测器模块与美国VDI公司的同频段检测器模块相比,检测灵敏度等指标相近。该器件在太赫兹安检成像应用中具有很好的应用前景。 InP/InGaAs Schottky Barrier Diodes(SBDs)detectors,due to their high electron mobility and low barrier material characteristics,have a very high voltage response sensitivity and are widely used in highly sensitive terahertz wave detection technology.To further reduce device parasitic effects and enhance its high-frequency performance,a novel structure of substrate-free single-mesa T-junction Schottky device is proposed,with a cutoff frequency of 9.5 THz.Based on the novel structure of InP/InGaAs Schottky device technology,terahertz detector modules for multiple frequency bands such as 220~330 GHz,30~500 GHz,400~600 GHz,and 500~750 GHz have been developed.Compared with the detectors of the same frequency band from VDI Company in the United States,the detection sensitivity and other indicators are similar,indicating that the device has a promising application prospect in terahertz security imaging.

作者周静涛金智苏永波史敬元丁武昌张大勇杨枫刘桐 ZHOU Jingtao;JIN Zhi;SU Yongbo;SHI Jingyuan;DING Wuchang;ZHANG Dayong;YANG Feng;LIU Tong(Institute of Microelectronics,Chinese Academy of Sciences,Beijing 100029,China)

机构地区中国科学院微电子研究所

出处《太赫兹科学与电子信息学报》 2025年第1期40-43,共4页 Journal of Terahertz Science and Electronic Information Technology

关键词太赫兹检测器肖特基二极管(SBDs) T型结无衬底单台面 terahertz detector Schottky Barrier Diodes(SBDs) T-junction substrate-free single-mesa

分类号 TN717 [电子电信—电路与系统]

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参考文献5

1洪伟,陈喆,周培根,陈继新,彭志刚,王佐钧.毫米波太赫兹集成电路与工艺[J].微波学报,2023,39(5):1-18. 被引量：20
2马凯学,张蕾.射频与毫米波功率放大器新进展[J].微波学报,2023,39(5):92-98. 被引量：11
3周静涛,杨成樾,葛霁,金智.Planar InP-based Schottky barrier diodes for terahertz applications[J].Journal of Semiconductors,2013,34(6):54-57. 被引量：2
4刘晓宇,张勇,夏德娇,任田昊,周静涛,郭栋,金智.A High-Sensitivity Terahertz Detector Based on a Low-Barrier Schottky Diode[J].Chinese Physics Letters,2017,34(7):47-50. 被引量：1
5任田昊,张勇,延波,徐锐敏,杨成樾,周静涛,金智.A High Performance Terahertz Waveguide Detector Based on a Low-Barrier Diode[J].Chinese Physics Letters,2016,33(6):6-8. 被引量：1

二级参考文献26

1Liu L, Hesler J L, Xu H Y, et al. A broadband quasi-optical terahertz detector utilizing a zero bias Schottky diode. IEEE Microw Wireless Compon Lett, 2010, 20(9): 504.
2Semenov A, Cojocari O, Hubers H, et al. Application of zero-bias quasi-optical Schottky-diode detectors for monitoring short-pulse and weak terahertz radiation. IEEE Electron Device Lett, 2010, 31(7): 674.
3Siles J V, Grajal J, Carlo A D. Design of submillimeter Schottky mixers under flat-band conditions using an improved drift— diffusion model. IEEE Microw Wireless Compon Lett, 2009, 19(3): 167.
4Thomas B, Maestrini A, Gill J, et al. A broadband 835-900-GHz fundamental balanced mixer based on monolithic GaAs membrane Schottky diodes. IEEE Trans Microw Theory Tech, 2010, 58(7): 1917.
5Chattopadhyay G. Technology capabilities and performance of low power teraherz sources. IEEE Trans Terahertz Sci Technol, 2010, 1(1): 33.
6Lee C, Ward J, Lin R, et al. A wafer-level diamond bonding process to improve power handling capability of submillimeter-wave Schottky diode frequency multiplies. Proceedings of IEEE MTT-S Digest, Boston, MA, USA, 2009: 957.
7Sze S M. Physics of semiconductor devices. 2nd ed. New York: John-Wiley & Sons, 1981.
8Hesler J L, Crowe T W. Responsivity and noise measurements of zero-bias Schottky diode detectors. 18th Intel Symp Space Terahertz Tech, Pasadena, March 2007.
9Bahl I, Bhartia P. Microwave solid state circuit design. 2nd ed. New York: John-Wiley & Sons, 2002.
10Tang A Y. Modelling of terahertz planar Schottky diodes. PhD Dissertation, Department of Microtechnology and Nanoscience, Chalmers University of Technology, Goteborg, Sweden, 2011.

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基于InP/InGaAs肖特基二极管的高灵敏太赫兹探测器

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