个人简介

黄旭光,教授/博士生导师。从事新型微纳集成与二维材料光子学、光纤传感与光电物联网技术、相干光通信与ROF关键技术研究。在Laser & Photonics Review(1区IF9.313)、Nanoscale(1区IF7.394)、Scientific Report(Nature子刊IF5.078)、Nanotechnology、Applied Physics Letters, Optics Letters、Optics Express和J. Lightwave Technology等SCI收录的国际和国内学术杂志上发表100余篇论文。总引用次数超过千次,其中在Optics Letters发表的一篇论文被引用200余次。具有长期科学研究和高科技开发的学术界和工业界两方面经验。担任多个国际和国内重要学术杂志审稿人。

教育经历

• 1979年—1983年,中山大学物理系本科,学士

 • 1986年—1992年,中山大学超快激光光谱学技术国家重点实验室硕博连读,理学博士 

研究工作经历

• 1983年–1986年,中山大学物理系,助教

 • 1992年–1996年,中山大学超快激光光谱技术国家重点实验室,讲师、副教授 

• 1996年–2003年,美国两所大学博士后 、高科技公司高级工程师

• 2011/02–2011/03, 新加坡南洋理工大学电机与电子工程学院,访问科学家

 •2012/02–2012/03,新加坡国立大学工程学院电子工程系,访问科学家

• 2004年–现在,华南师范大学,信息光电子科技学院,教授/博士生导师

主要成就

新型微纳集成与二维材料光子学研究方向:

1. 新型表面等离极化子纳米滤波器及传感等成果在OL、OE等杂志发表一系列30余篇。其中OL的文章引用超过200次,被评为OL杂志7年内15篇最高引用文章的第6篇。

2. 纳米自旋-涡旋光互作用集成波导的研究成果发表在1区的Nanoscale和OL杂志上。

3. 首次在国际上提出了石墨烯可调光波导及其在高速调制等应用,成果发表在 Laser & Photonics Review(影响因子 9.313)。

4. 首次提出了新型石墨烯可调光子晶体及其器件研究,成果发表在 Nanoscale(影响因子 7.394)。

5. 新型宽带偏振分束器的研究,实现了最小的低损偏振器件。在Nature子刊Scientific Reports发表(IF 5.078)。

6. 金属-类光子晶体及其滤波和光开关器件研究取得进展,在发表了多篇SCI收录的论文。 

光纤传感及物联网技术研究方向: 

7. 首次提出高精度光纤折射率传感技术、基于波分复用-菲涅耳反射的光纤折射率与温度传感器,发表在传感顶级杂志 Sensor & Actua.B(1区)和应用物理顶级杂志APL。

8. 首次基于纳米磁流体实现磁场测量;产学研合作研制了分布式光纤拉曼温度传感系统;与清华、中铁研制多路多探头的光纤光栅传感系统用于成渝高铁桥梁应用示范。

9. 开展了多种传感应用研究,包括浓度,温度传感度,酸碱度,磁场传感等。

10. 以新型特种功能光纤为传感核心,解决光纤传感及物联网相关的关键科技问题,探讨基于特种功能光纤的新型传感技术和传感物联网络结构。

主要专利

授权的发明专利:

1. 黄旭光;谢金玲,《一种光纤无线通信系统》,授权公告号:CN101714899B,授权公告日:2013.07.17;

2. 黄旭光; 陈基焕,《并行多点式光纤温度检测方法及传感器》,授权公告号:CN101762342B,授权公告日:2011.07.27;

3. 黄旭光; 邬怡婷; 苏辉《准分布式光纤浓度传感器》,授权公告号:CN100541175,授权公告日:2009.09.16;

4. 蒙红云;黄旭光,《光纤布拉格光栅折射率传感器》,授权公告号:CN101929955A,授权公告日:2012.07.18;

5. 蒙红云; 沈维; 黄旭光,《基于马赫-曾德干涉仪的可调谐平顶多信道光纤滤波器》,授权公告号:CN102062902B,授权公告日:2012.11.21;

6. 蒙红云; 武晓卫; 沈维; 黄旭光,《基于迈克尔逊干涉仪的光纤折射率传感器及其测量方法》,授权公告号:CN102419313B,授权公告日:2014.07.02;

7. 蒙红云; 薛红超; 王伟; 谭春华; 黄旭光,《基于多模干涉的光纤折射率与温度传感器及其测量方法》,授权公告号:CN103364105B,授权公告日:2015.03.25;

公布的发明专利:

8. 黄旭光; 苏伟衡;靳小平;陈銮雄,《基于表面等离激元的波导磁场/电流传感器及其装置》,申请公布号:CN105022004A, 申请公布日:2015.11.04, 申请号:2015103981954.

9. 黄旭光; 朱家胡; 陶金,《一种光纤无线传输系统》,申请公布号:CN103701530A,申请公布日:2014.04.02;

10. 黄旭光; 朱家胡; 陶金,《一种表面等离激元光波导滤波器》,申请公布号:CN103605189A,申请公布日:2014.02.26。

11. 黄旭光;徐伟;钟泽槟《基于光纤和无线传输的传感监测系统》CN103148890A,2013.06.12;

12. 蒙红云;姚琦琦;王伟;谭春华;黄旭光《一种光纤折射率和温度传感器及其测量方法》 CN103323058A,2013.09.25;

13. 武晓卫;沈维;王威;黄旭光《双通马赫-曾德干涉仪型偏振无关平顶梳状光纤滤波器》CN102608705A,2012.07.25;

14. 蒙红云;武晓卫;沈维;黄旭光《基于迈克尔逊干涉仪的光纤折射率传感器》,CN102419313A,2012.04.18。

主要论文

[1] Zan Hui Chen, Qi Long Tan, Jieer Lao, Yao Liang and Xu Guang Huang,“Reconfigurable and tunable flat graphene photonic crystal circuits”,Nanoscale, 7, 10912–10917 (2015). (SCI一区,影响因子7.394)

[2] Jieer Lao, Jin Tao, Qi Jie Wang, and Xu Guang Huang, “Tunable graphene-based plasmonic waveguides nano modulators and attenuators”, Laser & Photonics Reviews 8, No. 4, 569–574 (2014). (SCI一区,影响因子 9.313)

[3] Qilong Tan, X.G. Huang, “A Plasmonic based Ultracompact Polarization Beam Splitter on Silicon-on-Insulator Waveguides”, Scientific Reports 3, 2206(2013)(SCI 5.078,Nature子刊)

[4] Wen Zhou, X.G. Huang, “Long-range air-hole assisted subwavelength waveguides”, Nanotechnology, 24,235203 (2013), ( SCI 一区 3.842)

[5] Wen Zhou, X.G. Huang, “Compact filters and demultiplexers based on long-range air-hole assisted subwavelength waveguides”, OPTICS EXPRESS, 21(23),28456-28468 (2013) (SCI 二区 3.546)

[6] Wen Zhou, Xu Guang Huang, Qilong Tan, Yao Liang, Jieer Lao and Zanhui Chen, “Coherent-interference-induced transparency based on long-range air-hole assisted subwavelength waveguides”, J. Phys. D: Appl. Phys. 47 (2014) 475101

[7] “Ultra-compact electro-optical switches based on long-range air-hole assisted subwavelength waveguides”, J. Opt. Society Amer. B, 32(8), 1699-1704 / August (2015) (SCI三区,影响因子1.97).

[8] Yao Liang, Han Wen Wu, Bin Jie Huang and Xu Guang Huang, “Light beams with selective angular momentum generated by hybrid plasmonic waveguides”, Nanoscale 6(21): 12360-5 (2014). (SCI一区,影响因子6.739)

[9] Yao Liang and Xuguang Huang, “Generation of two beams of light carrying spin and orbital angular momenta of opposite handedness”, OPTICS LETTERS 39(17), 5074-5077 (2014)

[10] Xian-Shi Lin and Xu-Guang Huang*, "Tooth-shaped plasmonic waveguide filters with nanometeric sizes," Opt. Lett. 33, 2874-2876 (2008)(SCI)Selected for the January 5, 2009 issue of Virtual Journal of Nanoscale Science & Technology, 19(1)

[11] Wen Zhou, X.G. Huang, “Compact filters and demultiplexers based on long-range air-hole assisted subwavelength waveguides”, OPTICS EXPRESS, 21(23),28456-28468 (2013) (SCI 二区 3.546)

[12] Jin Tao, Xu Guang Huang, and Jia Hu Zhu, “A wavelength demultiplexing structure based on metal-dielectric-metal plasmonic nano-capillary resonators”, Optics Express, 18 (11), 11111-11116 (2010).

[13] Qin Zhang, Xu-Guang Huang, Xian-Shi Lin, Jin Tao, and Xiao-Ping Jin,“A subwavelength coupler-type MIM
optical filter”, Optics Express 17(9), 7549-7555 (2009).

[14] Jin Tao, Xu Guang Huang*, Xianshi Lin, Qin Zhang, Xiaopin Jin, “A narrow-band subwavelength plasmonic waveguide filter with asymmetrical multipleteeth-shaped structure”, Optics Express 17(16),13989-13994 (2009).

[15] Jia Hu Zhu, Xu Guang Huang and Xian Mei, “A Laser Structure Based on Metal-Dielectric-Metal Plasmonic Nanocavity”, Plasmonics: 7(1) (2012), 93-98.

[16] Xian Mei, Xu Guang Huang, Tao Jin, “A Sub-wavelength Electro-optic Switch Based on Plasmonic T-Shaped Waveguide”, Plasmonics, 6(4), 613-618 (2011).

[17] Jia Hu Zhu, Xu Guang Huang, Xian Mei, “Plasmonic Electro-Optical Switches Operating at Telecom Wavelengths”, Plasmonics, 6(3), 605-612 (2011).

[18] Hui Su, Xu Guang Huang*, “Fresnel Reflection based Fiber Optic Sensor for On-line Measurement of Solute Concentration in Solutions”,Sensors and Actuators: B,126:2 579–582 (2007)(SCI,2.6)

[19] Yi Ting Wu, Xu Guang Huang*, and Hui Su,“A quasidistributed fiber optic sensor for solute concentration measurement based on Fresnel reflection”,Appl. Phys. Lett. 91 (13), 131101-1--131101-3 (2007),(SCI)

[20] Xu Guang Huang*, Yi Ting Wu, Hao Yang and Yi Kun Xiong, “A quasi-distributed fiber- optic temperature sensor with a resolution of 0.07 centigrade based on Fresnel reflection”, J. Lightwave Technology, 27(14), 2583-2586 (2009).

[21] ia-Rong Zhao, Xu-Guang Huang, Wei-Xin He and Ji-Huan Chen, “High-resolution & temperature-insensitive fiber optic refractive index sensor based on Fresnel reflection modulated by Fabry-Perot interference”, J. Lightwave Technol. 28 (19), 2799-2803(2010).

[22] Ji-Huan Chen, Jia-Rong Zhao, Xu-Guang Huang, et al “Extrinsic fiber-optic Fabry-Perot interferometer sensor for refractive index measurement of optical glass” Applied Optics 49 (29), 5592-5596(2010)

[23] Jia Rong Zhao, Xu Guang Huang*,“A Fresnel-reflection-based fiber sensor for simultaneous measurement of liquid concentration and temperature,” J. Applied Physics, 106(8), pp. 083103-083103-5(2009).

[24] Hui Su, Xu Guang Huang*, “A Novel Fiber Bragg Grating Interrogating Sensor System Based on AWG Demultiplexing”,Optics Communication,275,196–200 (2007)(SCI)

[25] Jihuan Chen and Xuguang Huang, “Fresnel-reflection-based fiber sensor for on-line measurement of ambient temperature”, Optics Communications 283 (9), 1674-1677(2010)

[26] Ji-Huan Chen, Xu-Guang Huang, et al “Fabry-Perot interference-based fiber-optic sensor for small displacement measurement”, Optics Communications 283 (17), 3315-3319(2010)

[27] Rong Ping Hu, Xu Guang Huang*,“A Simple Fiber Optic Flowmeter based on Bending Loss,” IEEE Sensors Journal, 9(12) (2009).

[28] Chun Hua Tan, Xu Guang Huang*,Yu Ping Shi,“In situ measurements of the solubilities of salt–water systems by a fiber sensor”, Review of Scientific Instruments, 80, 034103 (2009)

[29] Jingtang Huang, Xuguang Huang* and Huawei Zhao,"Cost-effective and high-resolution wavelength interrogation unit using an incomplete asymmetric arrayed waveguide grating", Journal of Modern Optics,55(18), 2981–2988 (2008). (SCI)

[30] 86. HUANG Jing-Tang, HUANG Xu-Guang*, ZHAO Hua-Wei,"A Distributed Fibre Bragg Grating Sensor Interrogator Employing a Reformative Arrayed Waveguide Grating",Chin. Phys. Lett. 25(4), 1329 (2008) (SCI)

[31] Luan Xiong Chen, Xu Guang Huang*, Jia Hu Zhu, Guang Can Li, and Sheng Lan, "Fiber magnetic-field sensor based on nanoparticle magnetic fluid and Fresnel reflection," Opt. Lett. 36, 2761-2763 (2011).

[32] Xiao-Ping Jin, Xu-Guang Huang*, Jin Tao, et al., "A novel nanometeric plasmonic refractive index sensor," IEEE Transactions on Nanotechnology 9 (2), 134–137(2010). 

研究兴趣

微纳光子学 , 光纤通信与传感

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