光电子器件与集成功能实验室

孙军强
职务:教授
邮箱:jqsun@mail.hust.edu.cn
邮编:430074
电话:
地址:武汉光电国家实验室B204室

男,1965年生,华中科技大学教授,国家“863”计划项目首席专家,华中学者特聘教授,新世纪优秀人才计划获得者

  • 个人简介

    1994年6月,华中科技大学,光电子工程系,获得博士学位。
    1994年-1996年,于华中科技大学电工博后站从事博士后研究。
    1996年至今,任教于华中科技大学、武汉光电国家实验室,历任讲师、副教授、教授。

    其中:
    2000年9月-2001年9月,香港科技大学电子与电机工程系, 访问学者
    2005年6月-2005年12月,加拿大渥太华大学微波光子学实验室,高级访问学者
    2008年7月-2008年10月,香港理工大学电子与电机工程系, 高级访问学者


  • 研究领域

    集成光子与光电子器件,数字/微波信号的全光处理技术与器件,光纤通信与传感技术与器件

  • 主要学术成就

    主持的科研项目: 

    1. 国家863计划主题项目:“100Gb/s中长距离光互连芯片及模块”,4239万,2015.1~2017.12,项目编号:2015AA017100项目负责人,首席专家。

    2. 国家自然科学基金重点项目:“多功能有源无源光电子器件的集成芯片技术研究”,370万,2015.1~2019.12,项目编号:61435004项目负责人。

    3. 国家自然科学基金面上项目:“全光模式转换的新机理新技术研究,82万,2014.1~2017.12,项目编号:61377074,项目负责人。

    4. 中国电力工程顾问集团华北电力设计院有限公司合作项目:“10Gb/s波分遥泵放大超长距离光传输系统计算分析软件开发研究(编程及测试部分)”,50万元,2014.01~2015.04, 项目负责人。

    5. 国家自然科学基金面上项目:“微波信号全光处理的新机理新技术研究,76万,2012.1~2015.12,项目编号:61178002,项目负责人。

    6. 教育部新世纪优秀人才支持计划项目,“基于PPLN光波导的全光信号处理技术研究”NCET-04-0694,50万元,起止时间:2005.1~2007.12,项目负责人。

    7. 国家863计划课题:基于光子学产生超宽带(UWB)微波的铌酸锂光波导及其器件研究” 2009AA03Z410,  92万元,起止时间:2009.5-2011.12项目负责人

    8. 国家自然科学基金面上项目:基于AlGaAs光波导产生超宽带(UWB)脉冲的新机理新技术研究” 60977044, 50万元,起止时间:2010.1-2012.12项目负责人

    9. 国家自然科学基金面上项目,“基于光纤激光器的可调谐太赫兹(THz)波产生的研究”,60678020,30万元,起止时间:2007.1~2009.12,项目负责人

    10. 国家自然科学基金面上项目,“多波长同时转换的新机理新技术研究”,60177015,17.0万元,起止时间:2002.1~2004.12,项目负责人。

    11. 国家自然科学基金面上项目,一种新颖的多波长激射环形掺铒光纤激光器的研究” 6977802511万,起止时间:1998.1-2000.12项目负责人。

    12. 国家“863”高技术计划课题,“DWDM光交换节点无信道串扰技术的研究”,2001AA12207230.0万元,起止时间:2001.11~2003.11,项目负责人

    13. 国家“863”高技术计划项目,“新型结构全光波长转换器的关键技术及产品化研究”,2002AA312160,100万元,起止时间:2002.7~2005.6,项目负责人

    14. 教育部博士点基金(优先发展领域)项目,基于受激布里渊散射的微波信号全光处理技术研究,40万元,2013.1~2015.12,项目编号:20120142130004项目负责人

    15. 湖北省自然科学基金创新团队研究计划,“新颖的光电子器件与智能光网络的研究”,20万,起止时间:2009.1-2010.12,项目负责人

    16. 湖北省杰出人才基金,“基于二阶非线性的可调谐波长转换技术研究”,2005ABB003,10.0万元,起止时间:2006.1~2007.12, 项目负责人

    17. 教育部博士点基金项目,“高速全光信号处理的新机理研究”20060487007,6万元,起止时间:2007.1~2009.12,项目负责人

    18. 中国电力工程顾问集团公司委托项目,“电力系统光纤通信超长站距传输技术的研究(遥泵放大子课题)”68万元,起止时间:2010.3~2012.12, 项目负责人

    19. 华为技术有限公司委托开发项目:“EDFA免调纤技术研究项目”,2012.3~2012.7,23万元,项目负责人,项目负责人。

    20. 武汉华之洋光电系统有限责任公司:应用于环境安全监控的分布式光纤温度与应变传感系统2012.72014.7, 55万元,项目负责人。

    21. 武汉市重点科技计划项目,“低串音的OXC交换节点模块研究”,2002100513008,50.0万元,起止时间:2002.1~2004.12, 项目负责人

    22. 华为科研基金项目:“基于铌酸锂光波导的新颖可调谐全光波长转换器”,YJCB2007034TR, 15万元,起止时间:2007.7~2008.12, 项目负责人

    近年来学术论文发表的情况:

    [1]  Jianfeng Gao, Junqiang Sun*, Jialin Jiang, Heng Zhou, and Yang Zhou, “Design and analysis of electro-absorption modulators with uniaxially stressed Ge/SiGe multiple quantum wells”, Optics Express, 2017, 25(10), pp. 10874-10884.

    [2]   Yang Zhou, Junqiang Sun*, Jialin Jiang, Ruiwen Zhang, Jianfeng Gao, Heng Zhou, “Analysis of light emission performance of pseudoheterostructure diode based on germanium micro-bridge”, Optics Communications, 2017, 397, pp. 153-160.

    [3]   Jianfeng Gao, Heng Zhou, Jialin Jiang, Yang Zhou, and Junqiang Sun*, “Design of low bias voltage Ge/SiGe multiple quantum wells electro-absorption modulator at 1550 nm”, AIP Advances, 7, 035317 (2017).

    [4]   Jialin Jiang, Junqiang Sun*, Yang Zhou, Jianfeng Gao, Heng Zhou, and Ruiwen Zhang, “Design and analysis of a CMOS-compatible distributed Bragg reflector laser based on highly uniaxial tensile stressed germanium”, Optics Express, 2017, 25(6), pp. 6497-6510.

    [5]   Heng Xie, Jing Shao, Zhaoxi Sun,*Junqiang Sun, “Simultaneous Measurement of Strain and Temperature Based on Radio-Frequency Demodulation”, IEEE Photonics Technology Letters, 2017, 29(7), pp. 623-626.

    [6]   Heng Zhou, Junqiang Sun*, Jianfeng Gao, Jialin Jiang, and Yang Zhou, “Design of compact and efficient polarization-insensitive taper coupler for SiGe photonic integration”, Optics Express, 2016, 24(21), pp. 23784-23797.

    [7]   Danqi Feng, Junqiang Sun*, and Heng Xie, “Simultaneous Realization of Frequency Multiplication and Single Sideband Modulation by Exploiting Nonlinear Birefringent Effect, IEEE Transactions on Microwave Theory and Techniques, 2016, 64(9), pp. 3010-3016.

    [8]  Danqi Feng, Junqiang Sun*, “Optical single sideband modulation based on a high-order birefringent filter using cascaded Solc-Sagnac and Lyot-Sagnac loops”, Optics Letters, 2016, 41(15), pp. 3659-3662.

    [9]  Jialin Jiang, Junqiang Sun*, “Theoretical analysis of optical gain in uniaxial tensile strained and n+-doped Ge/GeSi quantum Well”, Optics Express, 2016, 24(13), pp. 14525-14537.

    [10]  Ya Gao, Junqiang Sun*, Chaotan Sima, “Simultaneous high bit-rate format and mode conversion with a single tilted apodized few-mode fiber Bragg grating”, Optics Communications, 2016, 377, pp. 115-119.

    [11]   Ruiwen Zhang, Guodong Chen, Junqiang Sun*, “Analysis of acousto-optic interaction based on forward stimulated Brillouin scattering in hybrid phononic-photonic waveguides”, Optics Express, 2016, 24(12), pp. 13051-  13059.

    [12]   Heng Xie, *Junqiang Sun, Danqi Feng, “Simultaneous measurement of strain and temperature based on hybrid EDF/Brillouin laser”, Optics Express, 2016, 24(11), pp. 11475-11482.

    [13]  Shan, Yuanyuan, *Sun, Junqiang, Efficient evaluation of impairment induced by distributed fiber Raman amplifier using error vector magnitude techniques in unrepeated coherent communication system”, Optics Communications, 2016, 368, pp. 155-159.

    [14]  Heng Xie, *Junqiang Sun, Danqi Feng, “Compact Multiwavelength Brillouin Fiber Laser by Utilizing EDF as Hybrid Gain Media”, IEEE Photonics Journal, 2015, 7(12), pp. 1-10.

    [15]   Danqi Feng, *Junqiang Sun, Heng Xie,Control of the optical carrier to sideband ratio in optical double/single sideband modulation by the phase variation of RF signals”, Optics Communications, 2015, 353, pp. 30-34.

    [16]   Feng Danqi, Xie Heng, Qian Lifen, *Sun Junqiang, “Photonic approach for microwave frequency measurement with adjustable measurement range and resolution using birefringence effect in highly non-linear fiber”, 2015, Optics Express, 23(13), pp. 17613-17621.

    [17]   Chen, Guodong, Zhang Ruiwen, *Sun Junqiang, “On-chip optical mode conversion based on dynamic grating in photonic-phononic hybrid waveguide”, Scientific Reports, 2015, 5, 10346.

    [18]   Gao Ya, *Sun Junqiang, Chen Guodong,Demonstration of simultaneous mode conversion and demultiplexing for mode and wavelength division multiplexing systems based on tilted few-mode fiber Bragg gratings”, Optics Express, 2015, 23(8), pp. 9959-9967.

    [19]   Lifen Qian, Danqi Fen, Heng Xie, Junqiang Sun*“A novel tunable multi-wavelength Brillouin ber laser with switchable frequency spacing” Optics Communications, 2015, 340, pp. 74-79.

    [20]   Wu Qi, Okabe Yoji, Sun Junqiang, “Investigation of dynamic properties of erbium fiber laser for ultrasonic sensing”, Optics Express, 2014, 22(7), pp 8405-8419.

    [21]   Guodong Chen, Ruiwen Zhang, Junqiang Sun*, Heng Xie, Ya Gao, Danqi Feng, Huang Xiong, Mode conversion based on forward stimulated Brillouin scattering in a hybrid phononicphotonic waveguide”,  Optics Express, 2014, 22(26), pp.32060-32070.

    [22]   Danqi Feng, Heng Xie, Guodong Chen, Lifen Qian, Junqiang Sun*, “Simultaneous generation of a frequency-multiplied and phase-shifted microwave signal with large tunability”, Optics Express, 2014, 22(15), pp.18372-18378.

    [23]   Du Mingdi, Sun Junqiang*,” A metal cascaded resonant cavity structure to enhance responsivity of photodetctor”, Optics Communications, 2014, 323, pp. 134-137.

    [24]   Liao Jianfei, Sun Junqiang*, Du Mingdi, Qin Yi, “Highly Nonlinear Dispersion-Flattened Slotted Spiral Photonic Crystal Fibers”, IEEE Photonics Technology Letters, 2014, 26(4), pp. 380-383.

    [25]   Jing Shao and Junqiang Sun*,Photonic ultrawideband impulse radio shape modulation based on dual-filter tuning,” Optics Letters, 2013, 38(2), pp. 232-234.

    [26]   Yi Qin, Junqiang Sun,* Mingdi Du, and Jianfei Liao, “Experimental demonstration of tunable optical single sideband modulation and 1.5 Gb/s RoF downlink using stimulated Brillouin scattering,” Optics Communications, 290, 2013, pp. 158-162.

    [27]   Chen Tao, Sun Junqiang*, Li Linsen, “Modal theory of slow light enhanced third-order nonlinear effects in photonic crystal waveguides,” Optics Express, 2012, 20(18), pp.20043-20058.

    [28]    Jing Shao and Junqiang Sun*, “Photonic ultrawideband impulse radio generation and modulation over a fiber link using a phase modulator and a delay interferometer,”Optics Letters, 2012, 37(16), pp. 3471-3473.

    [29]    Yi Qin, Junqiang Sun,* Mingdi Du, and Jianfei Liao, “Variable single-passband narrowband optical filter based on forward stimulated interpolarization scattering in photonic crystal fiber,” Optics Letters, 2012, 37(17), pp. 3720-3722.

    [30]    Chen Tao, Sun Junqiang*, Li Linsen, “Proposal for Efficient Terahertz-Wave Difference Frequency Generation in an AlGaAs Photonic Crystal Waveguide,” Journal of Lightwave Technology, 2012, 30(13), pp. 2156-2162.

    [31]    Chen Tao, Sun Junqiang*, Li Linsen, “Design of a Photonic Crystal Waveguide for Terahertz-Wave Difference-Frequency Generation,” IEEE Photonics Technology Letters, 2012, 24(11), pp. 921-923.

    [32]    Shao Jing, Sun Junqiang*, “Filter-free ultra-wideband doublet pulses generation based on wavelength conversion and fiber dispersion effect,” Optics Communications, 2012, 285(12), pp. 2790-2793.

    [33]    Qin Yi, Sun Junqiang*, “Frequency sextupling technique using two cascaded dual-electrode Mach-Zehnder modulators interleaved with Gaussian optical band-pass filter,” Optics Communications, 2012, 285(12), pp. 2911-2916.

    [34]    Huang Tianye, Sun Junqiang*, Li Jia, “40-Gb/s All-Optical Clock Recovery Based on an Mode-Locked Semiconductor Fiber Laser Using Nonlinear Polarization Rotation,”IEEE Photonics Technology Letters, 2012, 24(8), pp. 682-684.

    [35]    Hu Zhefeng, Sun Junqiang*, Chen Fushen, “High speed optical differential Manchester code generator using nested Mach-Zehnder interferometers,” Optics Communications, 2012, 285(8), pp. 2057-2060.

    [36]    Du Mingdi, Sun Junqiang*, Cheng Wenlong, “THz Output Improvement in a Photomixer with a Resonant-Cavity-Enhanced Structure,” Chinese Physics Letters, 2012, 29(4), 044203.

    [37]    Kang Tan, Jing Shao, Junqiang Sun*, and Jian Wang, “Photonic ultra-wideband pulse generation, hybrid modulation and dispersioncompensation-free transmission in multi-access communication systems,” Optics Express, 2012, 20(2), pp.1184-1201.

    [38]    Li Linsen, Sun Junqiang*, “Theoretical investigation of phase-based all-optical NOT, XOR and XNOR logic gates based on AlGaAs microring resonators,” Journal of Modern Optics,  2012, 59(9), pp.809-813.

    [39]   Jianguan Tang, Junqiang Sun*, Liang Zhao, “A stable optical comb with double-Brillouin-frequency spacing assisted by multiple four-wave mixing processes, ”Optical Fiber Technology, 2011, 17(6), 608-611.

    [40]   Tianye Huang, Jia Li, Junqiang Sun*, “Photonic Generation of UWB Pulses Using a Nonlinear Optical Loop Mirror and Its Distribution Over a Fiber Link,” IEEE Photonics Technology Letters, 2011, 23(17), pp. 1255-1257.

    [41]   Tianye Huang, Jia Li, Junqiang Sun*, “All-optical UWB signal generation and multicasting using a nonlinear optical loop mirror,” Optics Express, 2011, 19(17), pp.15885-15890.

    [42]   Jianguan Tang, Junqiang Sun*, Liang Zhao, “Tunable multiwavelength generation based on Brillouin-erbium comb fiber laser assisted by multiple four-wave mixing processes,” Optics Express, 2011, 19(15), pp.14682-14689.

    [43]   Linsen Li, Junqiang Sun*, Tao Chen, “Second-Harmonic Generation in AlGaAs/Al(x)O(y) Artificial Birefringent Microring Resonators ,” IEEE Photonics Technology Letters, 2011, 23(8), pp. 465-467.

    [44]   Zhao L., Sun J. Q.*, “Investigation of the phase-locking behavior by utilizing self-phase- and cross-phase-modulation in cubic susceptibility medium: Theory and experiment,” Physical Review A, 2010, 82, 063831.

    [45]   Wang J., Sun J. Q.*, Sun Q., “Phase-erased wavelength/format conversion and demodulation of 40 Gbit/s DPSK assisted by periodically poled lithium niobate,Applied Physics B-Lasers and Optics, 2010, 98(4), pp.831-838.

    [46]   Wang J., Sun J. Q.*, “All-optical logic XOR gate for high-speed CSRZ-DPSK signals based on cSFG/DFG in PPLN waveguide,” Electronics Letters, 2010, 46(4), pp.288-289.

    [47]   Wang J., Sun J. Q.*, “All-optical ultrawideband monocycle generation using quadratic nonlinear interaction seeded by dark pulses,” IEEE Photonics Technology Letters, 2010, 22(3), pp. 140-142.

    [48]   Hu Z. F., Sun J. Q.*,  Shao J.,  Zhang X. L., “Filter-free optically switchable and tunable ultrawideband monocycle generation based on wavelength conversion and fiber dispersion,” IEEE Photonics Technology Letters, 2010, 22(1), pp. 42-44.

    [49]   Wang J., Sun Q. Z., Sun J. Q., Hu Z., “PPLN-based all-optical 40 Gbit/s ODB/AMI/FSK wavelength conversion and FSK logic NOT gate,” Applied Physics B-Lasers and Optics, 2009, 96(1), pp.135-139.

    [50]   Wang J., Sun Q. Z., Sun J. Q., “Tunable dual-channel multicasting all-optical 40 Gbit/s logic AND operation and format conversion for CSRZ signals,” Electronics Letters, 2009, 45(8), pp.420-422.

    [51]   He X. Y.,  Fang X.,  Liao C. R., Wang D. N., Sun J. Q., “A tunable and switchable single-longitudinal-mode dual-wavelength fiber laser with a simple linear cavity,” Optics Express, 2009, 17(24), pp. 21773-21781.

    [52]   Liu S., Dong X. Y., Sun J. Q., Shum P., “Free-spectral range tunable Fabry-Perot filter with superimposed fiber Bragg gratings,” Optics Communications, 2009, 282(24), pp. 4729-4732.

    [53]   Hong W., Li M. H., Zhang X. L.,  Sun J. Q., Huang D. X., “Dynamic analysis of all-optical wavelength conversion of differential phase-shift keyed signals based on semiconductor optical amplifier Mach-Zehnder interferometer,” Journal of Lightwave Technology, 2009, 27(24), pp. 5580-5589.

    [54]   Wang J., Sun Q. Z., Sun J. Q.*, “All-optical 40 Gbit/s CSRZ-DPSK logic XOR gate and format conversion using four-wave mixing,” Optics Express, 2009, 17(15), pp. 12555-12563.

    [55]   Wang J., Sun Q. Z., Sun J. Q.*“Ultrafast all-optical logic AND gate for CSRZ signals using periodically poled lithium niobate,” Journal of the Optical Society of America B-Optical Physics, 2009, 26(5), pp.951-958.[56]   Zhao L., Sun J. Q.*, “Investigation of tunable trap filter utilizing intense signal four wave mixing model in highly non-linear fiber,” Optics Communications, 2009, 282(14), pp. 2975-2982.

    [57]   Wang J., Sun Q. Z., Sun J. Q.*, Zhang X. L., “Experimental demonstration on 40 Gbit/s all-optical multicasting logic XOR gate for NRZ-DPSK signals using four-wave mixing in highly nonlinear fiber,” Optics Communications, 2009, 282(13), pp.2615-2619.

    [58]   Wang J., Sun J. Q.*, Zhang, X. L., Huang D. X.,  “All-optical ultrawideband pulse generation using cascaded periodically poled lithium niobate waveguides,”  IEEE Journal of Quantum Electronics, 2009, 45(3), pp. 292-299.

    [59]    Wang J., Sun Q. Z., Sun J. Q.*, Zhang W. W., “All-optical UWB pulse generation using sum-frequency generation in a PPLN waveguide,” Optics Express, 2009, 17(5), pp.3521-3530.

    [60]    Wang J., Sun J. Q.*, Zhang, X. L., Huang D. X.,  “All-optical format conversions using periodically poled lithium niobate waveguides,”  IEEE Journal of Quantum Electronics, 2009, 45(2), pp. 195-205.

    [61]    Zhang W. W., Sun, J. Q.*; Wang J., Cheng C.; Zhang, X. L., “Ultra-wideband pulse train generation based on turbo-switch structures, IEEE Photonics Technology Letters, 2009, 21(5), pp. 271-273. 

    [62]    Wang J., Sun Q. Z., Sun J. Q.*, “All-optical 40 Gbit/s single-to-dual-channel simultaneous CSRZ wavelength conversion and format conversion,” Electronics Letters, 2009, 45(3), pp.175-177.

    [63]    Wang J., Sun J. Q.*, Zhang X. L., Huang D. X., Fejer M. M., “Optical phase erasure and its application to format conversion through cascaded second-order processes in periodically poled lithium niobate,” Optics Letters,  2008, 33(16), pp. 1804-1806.

    [64]    Wang J., Sun J. Q.*, Zhang X. F., Huang D. X., Fejer M. M., “Ultrafast all-optical three-input boolean XOR operation for differential phase-shift keying signals using periodically poled lithium niobate,” Optics Letters,  2008, 33(13), pp. 1419-1421.

    [65]    Zhang W. W., Sun, J. Q.*; Wang J., Cheng C.; Zhang X. L., Huang D. X., “Optical clock division based on dual-wavelength mode-locked semiconductor fiber ring laser,” Optics Express, 2008, 16(15), pp.11231-11236.[66]    Wang J., Sun J. Q.*, Zhang, X. L., Huang D. X., “All-optical tunable wavelength conversion with extinction ratio enhancement using periodically poled lithium niobate waveguides,” Journal of Lightwave Technology, 2008, 26(17), pp. 3137-3148.

    [67]   Hu Z. F.,  Sun, J. Q*, Liu L., Wang J., “All-optical tunable delay line based on wavelength conversion in semiconductor optical amplifiers and dispersion in dispersion-compensating fiber,” Applied Physics B-Lasers and Optics, 2008, 91(3-4), pp.421-424.

    [68]    Wang J., Sun J. Q.*, Zhang X. L., Huang D. X., “Proposal for PPLN-based all-optical NRZ-to-CSRZ, RZ-to-CSRZ, NRZ-DPSK-to-CSRZ-DPSK, and RZ-DPSK-to-CSRZ-DPSK format conversions,” IEEE Photonics Technology Letters, 2008, 20(9-12). pp.1039-1041.

    [69]   Wang J., Sun J. Q.*, Sun Q. Z., Wang D. L., Zhang X. F., Huang D. X., Fejer M. M.,, PPLN-based flexible optical logic AND gate,” IEEE Photonics Technology Letters, 2008, 20(3). pp.211-213.

    [70]   Wang J., Sun J. Q*, Zhang X. L., Huang D. X., “PPLN-based all-optical 40 Gbit/s three-input logic AND gate for both NRZ and RZ signals,” Electronics Letters, 2008, 44(6), pp.413-414.

    [71]   Wang J., Sun J. Q.*, Zhang, X. L., Liu D. M., Huang D. X., “Proposal and simulation for all-optical format conversion between differential phase-shift keying signals based on cascaded second-order nonlinearities,” Optics Communications, 2008, 281(19), pp. 5019-5024.

    [72]   Wang J., Sun J. Q.*, Sun Q. Z., Zhang X. L., Huang D. X., “All-optical dual-direction half-subtracter based on sum-frequency generation,” Optics Communications, 2008, 281(4), pp. 788-792.

    [73]    Liu J.,  Sun J. Q., Huang C. Q., Hu W., Chen M., “Improvement of spectral efficiency based on spectral splitting in photonic quantum-well structures,” IET Optoelectronics, 2008, 2(3), pp.122-127.

    [74]   Wang J., Sun J. Q.*, Sun Q. Z., Wang D. L., Zhou M. J., Zhang X. L., Huang D. X., “All-optical format conversion using a periodically poled lithium niobate waveguide and a reflective semiconductor optical amplifier,” Applied Physics Letters, 2007, 91(5), 051107.

    [75]   Wang J., Sun J. Q.*, Wang D. L., Zhou M. J., Zhang X. L., Huang D. X., Fejer M. M., “Experimental observation of all-optical non-returnto-zero-to-return-to-zero format conversion based on cascaded second-order nonlinearity assisted by active mode-locking,” Optics Letters, 2007, 32(16), pp.2462-2464.

    [76]   Wang J., Sun J. Q.*, Sun Q. Z., “Proposal for all-optical format conversion based on a periodically poled lithium niobate loop mirror,” Optics Letters, 2007, 32(11), 1477-1479.

    [77]   Wang J., Sun J. Q.*, Sun Q. Z., “Single-PPLN-based simultaneous half-adder, half-subtracter, and OR logic gate: proposal and simulation”, Optics Express, 2007, 15(4), pp.1690-1699.

    [78]   Wang J., Sun J. Q.*, Sun Q. Z., Wang D. L., Huang D. X., “Proposal and simulation of all-optical NRZ-to-RZ format conversion using cascaded sum- and difference-frequency generation,” Optics Express, 2007, 15(2), pp.583-588.

    [79]   Zhang W. W., Sun J. Q.*, Wang J., Liu L., “Multiwavelength mode-locked fiber-ring laser based on reflective semiconductor optical amplifiers,” IEEE Photonics Technology Letters, 2007, 19(19), pp.1418-1420.

    [80]   Wang J., Sun J. Q.* Sun Q. Z., “Proposal for all-optical switchable OR/XOR logic gates using sum-frequency generation,” IEEE Photonics Technology Letters, 2007, 19(8). pp. 541-543.

    [81]   Sun J. Q., Yuan X. H., Zhang X. L., Huang D. X., “Single-longitudinal-mode dual-wavelength fiber ring laser by incorporating variable saturable absorbers and feedback fiber loops,” Optics Communications, 2007, 273(1), pp. 231-237.

    [82]    Wang J., Sun J. Q.*, Zhang X. L., Yuan X. H., Huang D. X., “Experimental observation of tunable wavelength down- and up-conversions of ultra-short pulses in a periodically poled LiNbO3 waveguide”, Optics Communications, 2007, 269(1-3), pp.179-187.

    [83]    Sun J. Q., Huang L., “Photonic generation of frequency-switchable microwave signals exploiting polarization-induced spectrum splitting in fiber grating-based Fabry–Perot filters,” Optics Communications, 2007, 273(2), pp. 482-487.

    [84]    Wang J., Sun J. Q.*, Sun Q. Z., Zhang X. L., Huang D. X., “Simple realization of all-optical high-speed (40, 80 and 160 Gbs−1) XOR and OR logic gates using LiNbO3 waveguides,” Journal of Optics A: Pure and Applied Optics, 2007, 9(10), pp.811-819.

    [85]    Wang J., Sun J. Q.*, Sun Q. Z., Wang D. L., Zhou M. J., Zhang X. L., Huang D. X.  Fejer M.M., “Dual-channel-output all-optical logic AND gate at 20 Gbit/s based on cascaded second-order nonlinearity in PPLN waveguide,” Electronics Letters, 2007, 43(17), pp.236-238.

    [86]   Guan A. H., Sun J. Q.* and Li F. L., “Low crosstalk improved dilated Benes networks for photonic switching,” IET Optoelectronics, 2007, 1(1), pp. 31–35.

    [87]    Wang J., Sun J. Q.*, Sun Q. Z., “Experimental observation of a 1.5 μm band wavelength conversion and logic NOT gate at 40 Gbit/s based on sum-frequency generation,” Optics Letters, 2006, 31(11), pp. 1711-1713. [88]    Wang J., Sun J. Q.*, Luo C. H., Sun Q. Z., “Flexible all-optical wavelength conversions of 1.57-ps pulses exploiting cascaded sum- and difference frequency generation (cSFG/DFG) in a PPLN waveguide,” Applied Physics B-Lasers and Optics, 2006, 83(4), pp.543-548.

    [89]   Wang J., Sun J. Q.*, Kurz J. R., Fejer M. M., “Tunable wavelength conversion of ps-pulses exploiting cascaded sum- and difference frequency generation in a PPLN-fiber ring laser”, IEEE Photonics Technology Letters, 2006, 18(20), pp. 2093-2095.

    [90]    Sun J. Q., Liu D. M., Huang D. X., “Simultaneous wavelength conversion and pulse compression exploiting cascaded second-order nonlinear processes in LiNbO3 waveguides,” Optics Communications, 2006, 259(1), pp. 321-327.

    [91]    Sun J. Q., Yuan X. H., Zhang X. L., Huang D. X., “Single-longitudinal-mode fiber ring laser using fiber grating-based Fabry–Perot filters and variable saturable absorbers,” Optics Communications, 2006, 267(1), pp. 177-181.

    [92]   Sun J. Q., Wang J., Simulation of optical NOT gate switching by sum-frequency generation in LiNbO3 waveguides,” Optics Communications, 2006, 267(1), pp. 187-192.

    [93]    Wang J., Sun J. Q.*, Li J., Guo Y. J., “Single-to-dual channel wavelength conversion of picosecond pulses using PPLN-based double-ring fibre laser,” Electronics Letters, 2006, 42(4), pp.236-238.

    [94]    Cao H., Sun J. Q.*, Chen G. J., Huang D. X.,“A novel dispersionless comb gain equalizer for fiber optical parametric amplifier, Fiber and Integrated Optics2006, 25(4), pp. 279-286.

    [95]    Wang J., Sun J. Q.*, Luo C. H., Sun Q. Z., Zhang X. L., Huang D. X., “Single-to-multiple channel wavelength conversions and tuning of picosecond pulses in quasi-phase-matched waveguides,” Chinese Physics Letters, 2006, 23(7), pp.1806-1809.

    [96]    Wang J., Sun J. Q.*, Luo C. H., Sun Q. Z., “Experimental demonstration of wavelength conversion between ps-pulses based on cascaded sum- and difference frequency generation (SFG +DFG) in LiNbO3 waveguides,” Optics Express, 2005, 13(19), pp.7405-7414.

    [97]    Sun J. Q., Yuan X. H., Liu D. M., “Tunable wavelength conversion between picosecond pulses using cascaded second-order nonlinearity in LiNbO3 waveguides,” Applied Physics B-Lasers and Optics, 2005, 80(6), pp.681-685.

    [98]    Sun J. Q., Li Y., Liu D. M., “Widely tunable long-period fiber gratings with interpolymers as sensitivity-enhanced materials,” Optics Communications, 2005, 249 (1-3), pp. 193-200.

    [99]    Sun J. Q., Ma Z. T., Liu D. M., Huang D. X., “Wavelength conversion between picosecond pulses using cascaded second-order nonlinearity in LiNbO3 waveguides,” Optical and Quantum Electronics, 2005, 37(5), pp.443-456.

    [100]    Junqiang Sun, Deming Liu, and Dexiu Huang, “Difference-frequency generation among ultrashort optical pulses in quasi-phase-matching waveguides,” Optical and Quantum Electronics, 2004, 36(6), pp.577-587.

    [101]    Xinliang Zhang, Ying Wang, Junqiang Sun, Deming Liu, and Dexiu Huang, “All-optical AND gate at 10 Gbit/s based on cascaded single-port-coupled SOAs,”Optics Express, 2004, 12(3), pp.361-366.

    [102]    Junqiang Sun, Xinliang Zhang, Deming Liu, Dexiu Huang, “Suppression of four-wave mixing in erbium-doped fiber amplifiers by utilizing laser oscillation”, Optics Communications, 2003, 225 (1-3), pp. 39-45.

    [103]    Junqiang Sun,  Wei Liu, “Multiwavelength generation by utilizing second-order nonlinearity of LiNbO3 waveguides in fiber lasers”,  Optics Communications, 2003, 224 (1-3), pp. 125-130.

    [104]    Junqiang Sun, “Theoretical study on cross-gain modulation wavelength conversion with converted signal feedback”, IEE Proceeding-Optoelectronics, 2003, 150(6), pp.497-502.

    [105]    Junqiang Sun, Wei Liu, Jing Tian, J. R. Kurz, M. M. Fejer, “Multichannel wavelength conversion exploiting cascaded second-order nonlinearity in LiNbO3 waveguides” IEEE Photonics Technology Letters, 2003, 15(12). pp. 1743-1745.

    [106]    Lirong Huang, Dexiu Huang, Junqiang Sun, Deming Liu“Spectral broadening of ultrashort optical pulse due to birefringence in semiconductor optical amplifiers”, Optics Communications, 2003, 223 (4-6), pp. 295-300.

    [107]    Wei Liu, Junqiang Sun*, Jonathan Kurz,Bandwidth and tunability enhancement of wavelength conversion by quasi-phase-matching difference frequency generation, Optics Communications, 2003, 216 (1-3), pp. 239-246.

    [108]    Hong Wei, Huang Dexiu, Sun Junqiang, Liu Deming, “Numerical simulation of recovery enhancement by a CW pump light in semiconductor optical amplifiers,Optics Communications, 2002, 214, pp.335-341.

    [109]    Junqiang Sun, Ying Zhang, Xinliang Zhang, “Multiwavelength lasers based on semiconductor optical amplifiers,” IEEE Photonics Technology Letters, 2002, 14(6), pp. 750-752.

    [110]    J. Sun, “Influence of crosstalk on the scalability of WDM cross-connect networks,” IEE Proceeding-Optoelectronics, 2002, 149(2), pp.59-64.

    [111]    Junqiang Sun, Xinliang Zhang, Deming Liu, Dexiu Huang, “Noninverted wavelength conversion using Fabry-Perot semiconductor optical amplifers,” Optics Communications, 2002, 207(1-6), pp.287-294.

    [112]    Junqiang Sun, “Relaxation of facet reflection restrictions in XGM wavelength converters,” Optics Communications, 2002, 206(1-3), pp.67-75.

    [113]  Junqiang Sun, Junlin Qiu, Dexiu Huang, “Multiwavelength erbium-doped fiber lasers exploiting polarization hole burning,” Optics Communications, 2000, 182(1-3), pp.193-197.

    [114]  Sun Junqiang, Qiu Junlin, Huang Dexiu, “Multiwavelength erbium-doped fiber laser exploiting intracavity polarization inhomogeneity”, SCIENCE IN CHINA(Series E), 2000, 43(2), 194-198.


    获得的授权国家发明专利情况

    [1] 孙军强,江佳霖,“一种基于集成光波导耦合器的波长解调装置”,专利号:ZL201410222293.8,2016年7月6日授权。

    [2] 孙军强,周钰杰,冯力群,“一种周期极化反转铌酸锂光波导”,专利号:ZL201110139041.5,2013年1月2日授权。IPC分类号:G02B6/122(2006.01)

    [3] 孙军强,周钰杰,冯力群,“一种铌酸锂光波导的制备方法”,专利号:ZL201110124344.X,2013年3月20日授权。IPC分类号:G02B6/138(2006.01)

    [4] 孙军强,唐健冠,吴奇,一种基于布里渊散射的分布式光纤传感系统,专利号:ZL201010505382.5,2012年1月25日授权。IPC分类号:G01K11/32(2006.01)

    [5] 孙军强,王健,“一种基于非线性光波导的全光波长转换装置”,专利号:ZL200810090831.7,2011年4月20日授权。IPC分类号:G02F1/35(2006.01)

    [6] 孙军强,陈金林,“一种啁啾相移光纤光栅及基于该光栅的光纤激光器”,专利号:ZL200810048013.0,2010年8月25日授权。IPC分类号:H01S3/083(2006.01)

    [7] 孙军强,王健,基于铌酸锂光波导环形腔的全光波长转换装置,专利号:ZL200610125224.0,2009年6月24日授权。IPC分类号:G02F1/35(2006.01)

    [8] 孙军强,王健,基于非线性光波导环形镜的全光码型转换装置,专利号:ZL200610166523.9,2008年12月10日授权G02F1/365(2006.01)

    [9] 孙军强,王健,一种非归零码到归零码全光码型转换装置,专利号:ZL200610166524.3,2008年12月10日授权IPC分类号:G02F1/35(2006.01)

    [10]孙军强,刘威,罗传红,差频型全光波长转换器,专利号:ZL03125348.2,2007年4月4日授权IPC分类号:G02F1/37

    [11]孙军强,李凡龙,一种用于全光交换节点中的N×N光交换结构,专利号:ZL02138769.9,2005年1月19日授权IPC分类号:H04J14/02

     

     


  • 获奖与荣誉称号

    • 2015年获教育部高等学校自然科学一等奖,奖励名称:“多维光信息传输和处理的基础研究”,排名第二

    • 2009年获教育部高等学校自然科学二等奖,奖励名称:“脉冲光学二阶非线性理论及其在高速全光信号处理中的应用研究”,排名第一

    • 2009年获湖北省自然科学一等奖,奖励名称:多信道光通信网络光信号处理器件基础性问题的研究,排名第三

    • 2006年获湖北省科技进步二等奖,奖励名称:“光无线通信器件和系统技术研究”,排名第四

    • 2004年获教育部新世纪优秀人才计划资助

    • 2004年获教育部提名国家自然科学奖一等奖(高等学校自然科学一等奖),奖励名称:“基于能带剪裁的SOA理论研究及其应用”,排名第四 

    • 2004年度湖北省自然科学二等奖,奖励名称:“半导体光放大与全光通信光波处理的研究”,排名第三

    • 2009年获全国优秀博士论文提名奖指导教师奖

    • 2010年华中科技大学师德先进个人奖

    • 2011年华中科技大学“三育人积极分子”称号

    • 2012年华中科技大学“师表奖”

  • 主要学术兼职

    • 2015.1-至今:Technical program subcommittee on SPIE Photonics West 2016 and 2017

    • 2015-至今:中国仪器仪表学会光机电技术与系统分会第三届理事会理事

    • 2015-至今:中国光学学会光电子技术专业委员会第八届委员会委员

    • 2007,2009,2010年:Technical program subcommittee on Optoelectronic Materials and Devices (SC2) of APOC 2007,2009, 2010。

    • 2007年-2010年:任POEM会议中OEDI分会的组委会主席。

    • 2004年-2006年:国家自然科学基金委员会第十届信息科学部专家组评审成员。

    • 2004年-2008年:中国物理学会《Chinese Physics Letters》特约评审。

    • 2006年至今:《激光技术》第九、十、十一届编辑委员会委员。

    • 2007年10月至今:第二届湖北省引进国外技术、管理人才项目专家咨询委员会常设专家组成员。

  • 招生信息

        主要从事基于光学非线性效应的全光数字/模拟信号的全光处理研究,面向光通信和光传感领域的重大需求、交叉学科及应用研究,欢迎物理学、光信息科学与技术、光电信息工程、电子科学与技术、通信与信息系统等专业的同学报考。