深圳大学  舒国响


办公室:沧海校区致腾楼917   办公室电话:0755-26651310   邮箱:gxshu@szu.edu.cn

 

舒国响博士,深圳大学电子与信息工程学院助理教授,特聘副研究员,硕士生导师。20176月博士毕业于电子科技大学,同年9月加入深圳大学。于2015-2017年赴英国University of Strathclyde进行博士生联合培养。从事大功率毫米波/太赫兹真空电子器件、毫米波/太赫兹无源器件等方向的研究,研发器件是高精度雷达、高数据率无线通信和电子对抗等整机系统的核心电子器件。从事《微波工程》和电子科技专业综合实验(微波模块)等课程的教学工作。

目前已发表学术论文60余篇,其中一作学术论文30余篇,IEEE期刊论文18篇,包括Appl. Phys. Lett. (APL)IEEE Electron Device Lett.EDL)、IEEE Trans. Electron Devices (TED)IEEE Trans. Microw. Theory Techn. (TMTT)IEEE Trans. THz Sci. Technol. (TST)等业内著名SCI期刊。发表在APLIEEE EDL上的学术成果均被选为“Editor's Pick”。在国际学术会议进行口头报告9次,其中邀请报告1次,作为分会主席1次。申请国防/中国发明专利11个,其中已授权4个。主持国家、省级、市级和校级等各类科研项目共6项。目前为IEEE member,担任IEEE EDL/TEDIEEE Trans. Plasma Sci.International Journal of Numerical Modelling: Electronic Networks, Devices and FieldsPlasma Science and Technology、雷达学报等期刊审稿人。目前为深圳市孔雀计划团队核心成员,深圳市海外高层次人才(C类孔雀人才),南山区C类领航人才。

长期招聘电磁场与微波技术、毫米波与太赫兹技术等相关方向的博士后。热烈欢迎本科生前来报考研究生[学术型硕士:080900电子科学与技术(电磁场与微波技术研究方向);专业型硕士:085400电子信息]。热烈欢迎感兴趣的本科生走进实验室。Researchgate学术主页:https://www.researchgate.net/profile/Guoxiang_Shu

一、主要研究方向

1) 大功率毫米波/太赫兹放大器(带状注行波管/回旋行波管);

2) 大功率毫米波/太赫兹振荡器(扩展互作用振荡管/返波管);

3) 毫米波/太赫兹无源器件(耦合器、模式变换器、滤波器、谐振器和毫米波天线等);

4) 毫米波生物传感器及介质材料复介电常数测试。

二、近几年主持的科研项目

1)国家自然科学基金青年基金(批准号:619012772020.01-2022.12, 24.5万元)

2)广东省教育厅青年创新人才项目(批准号:2018KQNCX2152019.1-2021.12, 5万元)

3)深圳市基础研究自由探索项目(批准号:JCYJ201803051244064702019.01-2020.12, 50万元)

4)深圳市基础研究面上项目(批准号:JCYJ20190808145801658, 2020.05-2023.0530万元)

5)深圳大学青年教师基金(批准号:20180462018.01-2019.12, 6万元)

6)深圳市高端人才启动项目(2019.1-2021.12300万元)

三、代表性期刊论文

[1]  G. X. Shu, C. J, Ruan, W. He, “Study of H-band high-order overmoded power couplers for sheet electron beam devices,”IEEE Trans. Microw. Theory Techn., vol. 68, no. 6, pp. 2251-2258, Jun. 2020. (中科院二区,微波领域旗舰期刊)

[2]  G. X. Shu, J. Deng, Z. Huang, L. Chen, J. Lin, B. Hong, and W. He, “Design and measurement of a terahertz band rectangular TE20 mode power coupling structure for high-order overmoded multiple sheet electron beam devices,” IEEE Electron Device Lett., vol. 41, no. 6, pp. 920-923, Jun. 2020. (中科院二区,电子器件领域旗舰期刊)

[3]  G. X. Shu, J. Deng, L. Xie, G. Liu, L. Zhang, J. X. Wang, Z. F. Qian, W. He, “Design, fabrication, and cold test of a high frequency system for an H-band sheet beam travelling wave tube,” IEEE Trans. THz Sci. Technol., vol. 10, no. 3, pp. 292-301, May. 2020. (太赫兹技术领域旗舰期刊)

[4]  G. X. Shu, Z. R. Cai, Y. C. Li, G. Liu, W. He, “Wideband rectangular TE10 to TEn0 mode converters for terahertz-band high-order overmoded planar slow-wave structures,” IEEE Transactions Electron Devices, vol. 67, no. 3, pp. 1259-1265, Mar. 2020. (电子器件领域旗舰期刊)

[5]  G. X. Shu, Z. F. Qian, W. He, “Design and measurement of an H-band rectangular TE10 to TE20 mode converter,” IEEE Access, vol. 8, pp. 37242-37249, Feb. 2020. (中科院二区)

[6]  G. X. Shu, G. T. Zhang, and W. He, “Design and measurement of a terahertz double staggered grating waveguide with an arc-shaped beam tunnel,” IEEE Trans. Electron Devices. vol. 66, no. 11, pp. 3970-3975, Nov. 2019. (电子器件领域旗舰期刊)

[7]  G. X. Shu, J. X. Wang, G. Liu, J. X. Wang, Z. F. Qian, W. He, “Design and millimeter-wave measurement of a wideband power coupling structure for sheet electron beam devices,” IEEE Trans. Electron Devices, vol. 66, no. 7, pp. 3171-3177, Jul. 2019. (电子器件领域旗舰期刊)

[8]  G. X. Shu, L. Zhang, H. Yin, J. Zhao, A. D. R. Phelps, A. W. Cross, G. Liu, Y. Luo, Z. F. Qian, and W. He, “Experimental demonstration of a terahertz extended interaction oscillator driven by a pseudospark-sourced sheet electron beam,” Appl. Phys. Lett., vol. 112, no. 3, pp.033504-1-033504-4, 2018. (中科院二区,Editor’s picks)

[9]  G. X. Shu, H. Yin, L. Zhang, et al, “Demonstration of a planar W-band, kW-level extended interaction oscillator based on a pseudospark-sourced sheet electron beam,” IEEE Electron Device Letters, vol. 39, no. 3, pp. 1-4, Mar. 2018. (中科院二区,封面报道,Editor’s picks)

[10] G. X. Shu, J. X. Wang, G. Liu, and Z. F. Qian, “Study of performance improvement for a Q-band sheet beam traveling-wave tube,” IEEE Transactions Electron Devices, vol. 65, no. 9, pp.3970-3975, Sep. 2018. (电子器件领域旗舰期刊)

[11] G. X. Shu, G. Liu, and Z. F. Qian, “Simulation study of a high-order mode terahertz radiation source based on an orthogonal grating waveguide and multiple sheet electron beams,” Optics Express, vol. 26, no. 7, pp. 1-9, Apr. 2018. (中科院二区)

[12] G. X. Shu, G. Liu, L. Chen, H. Bambarandage, and Z. F. Qian, “Terahertz backward wave radiation from the interaction of high-order mode and double sheet electron beams,” Journal of Physics D: Applied Physics, vol. 51, no. 5, pp. 055107-1- 055107-6, 2018.

[13] G. X. Shu, W. He, L. Zhang, H. Yin, J. P. Zhao, A. W. Cross, A. D. R. Phelps, “Study of a 0.2 THz extended interaction oscillator driven by a pseudospark-sourced sheet electron beam,” IEEE Transactions Electron Devices, vol. 63, no. 12, pp. 4955-4960, Dec. 2016. (电子器件领域旗舰期刊)

[14] G. X. Shu, J. X. Wang, G. Liu, L. Y. Yang, Y. Luo, S. F. Wang, “An improved slow-wave structure for the sheet-beam traveling-wave tube,” IEEE Transactions Electron Devices, vol. 63, no. 5, pp. 2089-2096, May. 2016. (电子器件领域旗舰期刊)

[15] G. X. Shu, Y. Luo, Q. S. Zhang, J. Su, L. Wang, Y. Xu, S. F. Wang, “Millimeter wave measurement of the low-loss dielectric in vacuum electronic devices with reflection-type hemispherical open resonator,” J. Infrared Milli Terahz Waves, vol. 36, no. 5, pp. 556-568, Mar. 2015.

[16] G. X. Shu, J. X. Wang, G. Liu, Y. Luo, S. F. Wang, “Design and microwave test of an ultra-wideband input/ output structure for sheet beam travelling wave tubes,” Review of Scientific Instruments, vol. 86, no. 6, pp. 064703-1-064703-7, 2015.

[17] G. X. Shu, J. X. Wang, G. Liu, L. Y. Yang, Y. Luo, S. F. Wang, “Theoretical analysis and design optimization of wideband input/output branch waveguide couplers for a sheet beam traveling wave tube,” Journal of Electromagnetic Waves and Applications, vol. 54, no.3, pp. 2002-2013, Aug. 2015.

[18] D. Chen, B. Zhang, X. He, X. L. Huang, G. Liu*, G. X. Shu*, “Terahertz biosensing metamaterial absorber for virus detection based on spoof surface plasmon polaritons,” International Journal of RF and Microwave Computer-Aided Engineering, vol. 28, pp. 1-7, May. 2018.(通信作者)

[19] J. X. Wang, G. X. Shu, G. Liu, et al. Ultra-wideband coalesced-mode operation for a sheet-beam traveling-wave tube. IEEE Transactions Electron Devices, vol. 63, no. 1, pp. 504-511, 2016.

[20] J. X. Wang, Q. Z. Tian, X. X. Li, G. X. Shu, et al., “Theory and experiment investigate of a 400-kW Ku-band Gyro-TWT with mode selective loss loading structure”, IEEE Transactions Electron Devices, vol. 64, no. 2, pp. 550-555, 2017.

四、代表性会议论文

[1] G. X. Shu, J. X. Wang, W. He, et al., “Study of a high frequency system for sub-terahertz sheet beam travelling wave tubes,” 11th IEEE International Conference on Microwave and Millimeter Wave Technology (ICMMT), Guangzhou, China, 2019, pp:1-3. (Oral)

[2] H. Xiong, G. X. Shu*, L. X. Cao, et al., “Design of an input/output coupler for 0.22 THz sheet beam travelling wave tubes,” Photonics & Electromagnetics Research Symposium (PIERS), Xiamen, China, 2019, pp:1-2. (Invited)

[3] G. X. Shu, W. He, et al., “Preliminary study of a 0.3 THz resonant slow wave structure for a sheet beam extended interaction oscillator,” 2019 IET PhD Candidates Academic Seminar (China) on Vacuum Electronics, Beijing, China, 2019, pp:1-2. (Oral, Session Chair)

[4] G. X. Shu, W. He, L. Zhang, et al., “Preliminary Study of a Sub-terahertz Sheet Electron Beam Traveling Wave Tubes,” 9th UK-Europe-China Workshop on mm-waves and THz Technologies, London, UK, 2019, pp:1-2.

[5] G. X. Shu, L. Zhang, H. Yin, et al., “Experimental study of terahertz radiation sources based on a planar slow wave structure and a pseudospark-sourced sheet electron beam,” IEEE 43rd International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz), Nagoya, Japan, 2018, pp:1-2. (Oral)

[6] G. X. Shu, C. Q. Zhou, H. Xiong, L. Chen, G. Liu, Z. F. Qian, “Study of a high-order mode terahertz backward wave oscillator driven by multiple sheet electron beams,” IEEE 11th UK-Europe-China Workshop on Millimetre-wave and Terahertz Technologies (UCMTT), Hangzhou, China, 2018, pp:1-2. (Oral)

[7] G. X. Shu, W. He, L. Zhang, et al., “Preliminary design of a G-band extended interaction oscillator driven by a sheet electron beam,” IET Colloquium on Millimetre-wave and Terahertz Engineering & Technology, London, UK, 2016, pp:1-3. (Oral)

[8] G. X. Shu, W. L. He, L. Zhang, H. B. Yin, J. Zhao, A. D. R. Phelps and A. W. Cross, “A 0.2 THz extended interaction oscillator driven by a pseudospark-sourced sheet electron beam,” Technological Plasma Workshop, Coventry, UK, 2016, pp:1. (Oral)

[9] G. X. Shu, W. He, L. Zhang, et al., “Preliminary design of a 0.36 THz sheet electron beam extended interaction oscillator,” National Vacuum Electronics Conference. Lancaster, UK, 2016, pp:1-2. (Oral)

[10] G. X. Shu, J. X. Wang, G. Liu, et al., “Design and cold test of a novel broadband output coupler for sheet beam travelling tube,” 15th IEEE International Vacuum Electronics Conference, Beijing, China, 2015, pp:1-2. (Oral)

五、代表性专利

[1] 舒国响,钱正芳,熊浩,曹利红,等.一种多孔波导和反射腔加载的Y形分支波导耦合器[P],中国发明专利,201810990250.2(进入实质审查阶段)

[2] 舒国响,钱正芳,熊浩,等.一种具有曲线轮廓的单栅慢波结构[P],中国发明专利,201810615288.1 (进入实质审查阶段)

[3] 舒国响,钱正芳,熊浩,等.一种矩形金属柱加载的交错栅慢波结构[P],中国发明专利,201810614351.X (进入实质审查阶段)

[4] 舒国响,何文龙,等.一种基于H-T功分网络的TE10-TEn0模式变换器[P],中国发明专利,201910447076.1(已申请)

[5] 舒国响,何文龙,等.一种用于高阶过模平面慢波结构冷腔测试的TE10-TEn0模式变换器[P],中国发明专利,201910447962.4(已申请)

[6] 舒国响,何文龙,等.应用于高阶过模带状多注器件的输入/输出功率耦合装置[P],中国发明专利,202010357203.1(已申请)

[7] 王建勋,舒国响,刘国,等.一种带状注行波管或返波管的输入耦合装置[P],国防发明专利,ZL 201518000516.1(已授权)

[8] 王建勋,舒国响,刘国,等.一种用于带状注行波管的输入耦合装置[P],国防发明专利,ZL 201518000518.0(已授权)

[9] 刘国,王建勋,杨利亚,舒国响.一种宽频带工作带状束输入输出耦合结构[P],国防发明专利,ZL 201518000517.6(已授权)

[10] 王建勋,杨利亚,刘国,舒国响,等.一种带状注器件的曲线耦合输入输出装置[P],中国发明专利,CN104851767A(已授权)