|
|||||||||||||||||
|
庞拂飞 教授,博士生导师,博士 |
||||||||||||||||
办公室: |
威廉williamhill体育宝山校区(东区)翔英楼535室;威廉williamhill体育宝山校区(东区)12楼B409室 |
||||||||||||||||
通信地址(邮政编码): |
上海市南陈路333号(200444) |
||||||||||||||||
电话: |
(86)21-66136329 |
||||||||||||||||
电子邮件: |
ffpang@shu.edu.cn |
||||||||||||||||
个人主页: |
|||||||||||||||||
个人简介: 庞拂飞,教授,2014年获国家自然科学基金优秀青年基金资助。2001.9-2006.6在中国科学院上海光学精密机械研究所攻读博士学位(硕博连读);2006.7到威廉希尔从事科研和教学工作。依托于特种光纤与光接入网省部共建国家重点实验室培育基地(科技部-上海市),从事特种光纤器件、光纤传感、光纤通信等方面的研究工作;2010.7-2011.6在澳大利亚新南威尔士大学光纤研究中心做国家公派访问学者。目前发表学术论文200余篇,其中SCI检索100余篇;申请发明专利50项,其中已授权30项。主持国家自然科学基金重点项目2项,国家重点研发计划课题2项,国家重大科学仪器项目“子课题”1项,省部重点科研项目及企业委托横向项目多项。曾获上海市“曙光学者”、“科技启明星”、“晨光计划”及“人才发展资金”等资助;2013年获“上海市青年五四奖章”;2014年获上海市“育才奖”。2022年获上海市教学成果一等奖;2024年获仪器仪表学会教学成果二等奖;2022年获上海市科技进步一等奖等奖、中国光学工程学会科技进步一等奖。 学术经历:
研究领域: 光纤传感器、光纤通信技术 集成光波导技术 特种光纤设计、制备工艺 学术荣誉: 2024年获仪器仪表学会教学成果二等奖 2022年获上海市教学成果一等奖 2022年获上海市科技进步一等奖 2019年获上海市科技进步二等奖 2017年获国网上海市电力公司科技进步二等奖 2016年获上海市“曙光学者” 2016年获“上海市人才发展资金” 2014年获国家自然科学基金“优青”项目资助 2013年获上海市技术发明三等奖 2010年获上海市科委“科技启明星”人才项目的资助 2007年获上海市教育发展基金会首届“晨光计划”人才基金 学术兼职: Ø 《光学学报》网路版编委 Ø SCI期刊《Nature
Communications》、《Scientific Reports》《Sensor and Actuator B: Chemical》、《IEEE
Journal of Lightwave Technology》、《IEEE Photonics Technology
Letters》、《Optics Express》等评阅人 主持科研项目: 1.
国家重点研发计划课题,MEMS 光纤振动敏感元件设计制造及传感器封装(2023YFB3209502),2023-2026,在研 2.
国家自然科学基金联合重点基金项目:多侧芯手性耦合石英激光光纤材料结构与特性研究(U2241237),2023.01-2026.12,在研 3.
国家重点研发计划课题,光互连波导及光耦合技术(2019YFB1802901) 2020-2023,已结题 4.
国家自然科学基金面上项目:光涡旋模式光纤电流传感器关键技术研究(61975108),2020.01-2023.12,已结题 5.
国家自然科学基金重点项目,单芯多通道光涡旋长距离传输光纤关键制备技术(61635006),2017.01-2021.12,已结题 6.
国家重点研发计划课题,光纤传感器微结构设计及封装工艺研究(2016YFF0100603) 2016-2018,已验收 7.
国家自然科学基金优青项目:特种光纤材料与技术(61422507),2015.01-2017.12,已结题 8.
上海市科委重点项目:电力电缆局放声发射光纤传感监测技术研究(14DZ1201403),2014.07-2016.06,已验收 9.
上海市科委重点项目:面向大型光伏电站群的智能物联网技术研发(14511105602),2014.07-2016.06,已验收 10.上海市教委科研创新项目-重点项目:光印刷背板互连光波导理论及关键技术研究(14ZZ093),2014.01-2016.12,已结题 11.上海市科委重点支撑项目:面向电力系统安全的相干光时域反射光纤传感技术(13510500300),2013.06-2015.06,已验收 12.国家自然科学基金面上项目:稀磁半导体量子点掺杂石英磁光光纤研究(61275090),2013.01-2016.12,已结题 13.上海市科委“科技启明星”人才项目:包层模谐振光纤折射率和温度双参量传感关键技术研究(10QA1402600),2010.04-2012.03,已验收 14.国家自然基金青年基金项目:温度不敏感包层模谐振特种光纤传感机理研究(60807031),2009.01-2011.12,已结题 15.上海市教委创新项目:渐逝波激发量子点集成波导光放大器研究(10YZ12),2010.01-2011.12,已结题 16.上海市教育发展基金会“晨光计划”人才项目:包层模谐振特种光纤的理论、制备及特性研究(2007CG54),2007.11-2009.12,已结题 讲授课程: Ø 上海市一流本科课程:《电路与电子线路基础1》 Ø 新生研讨课《智能光纤,感知世界》 Ø 研究生课程《通信与信息技术进展》 公司产品: Ø 已毕业博士研究生:杨俊锋(2015级),马章微(2016级),王之凤(2018级)。 Ø 已毕业硕士研究生:梁文斌(2006级);刘奂奂(2007级);刘伦刚、章健(2008级);蓝鲁刚、周亭(2009级);陈石琼、吴利波(2010级);陈莉、赵颖、马宵(2011级);徐慧、冯业彬、顾鑫(2012级);贺梦婷、陈鹏飞、郭丽丽(2013级);洪琳、张统治、屠天禺、王建辉(2014级);徐金、李先进、吕龙宝(2015级);黄蕾霖、肖磊、郑浩强、李鲁川(2016级);陈真、沈诗、郭子铭、陈亚晴(2017级);陈锦涛、刘智超、吴豪(2018级);邱建恒、王鹏冲、魏伟、刘帅帅、孙若琦(2019级);卢晓、薛小波、江琪、胡勇、操前(2020);顾蕴喆、徐星雨、唐奕、杨毅(2021级)。 Ø 在读博士研究生:陈丽飞(2017级),向丽娜(2020级),文菁(2021级),王贤(2023级),刘学诚(2024级)。 Ø 在读硕士研究生:陈雪丽、陈洛、郭恒、祝俊杰(2022);逄型魁、辛悦、闫晓雨(2023)。 Ø 刘奂奂的硕士论文被评为“2011年上海市研究生优秀成果(学位论文)”。 Ø 赵颖的硕士论文被评为“2015年上海市研究生优秀成果(学位论文)”。 代表性学术论文(近五年): 1. Xingyu Xu, Xiao Lu, Fufei Pang*, Na Chen, Heming Wei, Liang
Zhang, Qianwu Zhang, Tingyun Wang. Overcoming oxygen inhibition in UV
photolithography for the fabrication of low-loss polymer waveguides, Optics
Letters, 2024, 49(9): 2369-2372. 2. Lina Xiang, Fufei Pang*, Zhongyin Xiao, Liang Zhang,
Heming Wei, Mengshi Zhu,
Siddharth Ramachandran, Tingyun Wang. Vibration-insensitive polarimetric fiber optic current sensor based on orbital
angular momentum modes in an air-core optical fiber, Optics
Letters, 2024, 49(7): 1753-1756. 3. Liang Zhang*,
Haozhe Shou, Yiyang Feng, Zhengxuan Li, Mengshi Zhu, Heming Wei, Yingxiong Song, Fufei Pang*, Tingyun Wang. Self-injection locked low-noise
Brillouin random fiber laser via dynamic fiber grating for QAM coherent
communication, Applied
Physics Letters, 2024, 124(13): 131104. 4. Yi Tang, Mengshi Zhu, Fufei Pang*, Heming Wei, Liang Zhang, Wei Chen, Tingyun Wang. Distributed optical fiber magnetic
field sensor based on polarization-sensitive OFDR, Optics Express, 2024, 32(7): 11726-11736. 5. Yunzhe Gu, Fufei Pang*, Mengshi Zhu, Yi Tang, Yi Tang, Liang Zhang, Heming Wei, Tingyun Wang. Heterogeneous integrated optical fiber
with side nickel core for distributed magnetic field sensing, Optics
Express, 2024, 32(5): 7540-7552. 6. Liang Zhang*,
Han Wang, Yichun Li, Song Gao, Mengshi Zhu, Heming Wei, Fufei Pang*, Tingyun Wang. Towards high-sensitivity and
high-accuracy forward Brillouin scattering-based optomechanical temperature
sensing in thin-diameter fibers, Optics Express, 2024, 32(1): 586-598. 7. Heming Wei, Zhangli Wu, Yan Wei, Chen Wang, Haiyan
Zhang, Fufei Pang*,
Carlos Marques, Christophe Caucheteur, and Xuehao Hu. 3D printed Fabry-Perot
acoustic probe with a glass horn tube, Optics
and Laser Technology, 2024, 168: 109977. 8. Liang Zhang*,
Jilin Zhang, Fufei Pang*,
Tingyun Wang, Liang Chen, Xiaoyi Bao. Transient replica symmetry breaking in
Brillouin random fiber lasers, PhotoniX, 2023, 4(1): 33. 9. Heming Wei, Zhangli Wu, Kexuan Sun, Haiyan Zhang,
Chen Wang, Keming Wang, Tian Yang, Fufei Pang*, Xiaobei Zhang, Yingyun
Wang, and Sridhar Krishnaswamy. Two-photon 3D printed spring-based
Fabry-Pérot cavity resonator for acoustic wave detection and imaging, Photonics
Research, 2023, 11(5): 780-786. 10.Yan Wei,
Kexuan Sun, Heming Wei, Mengshi Zhu, Fufei Pang, Carlos Marques,
and Xuehao Hu. A Corrugated Diaphragm-Based Fabry-Perot Ultrasonic Sensor by
Two-Photon 3D Printing, IEEE Photonics Technology Letters, 2023, 35(20): 1078-1081. 11.Pengchong
Wang, Mengshi Zhu, Fufei Pang*, Heming Wei, Liang Zhang, Yana Shang, Wei Chen, and
Tingyun Wang. Cylindrical Vector Beams for Alternating Magnetic Field Sensing
Based on YIG Crystal, IEEE Photonics Technology Letters, 2023, 35(19), 1031-1034. 12.Heming
Wei, Kexuan Sun, Yan Wei, Mengshi Zhu, Haiyan Zhang, Fufei Pang,
Tingyun Wang, and Sridhar Krishnaswamy. Micro-3D printed Concanavalin A
hydrogel based photonic devices for high-sensitivity glucose sensing,
Optics Letters, 2023,
48(16): 4412-4415. 13.Heming
Wei, Long Han, Ruixue Yin, Tian Yang, Yunqi Liu, Chengbo Mou, Fufei
Pang, and Wang, Tingyun. Micro-3D printed Concanavalin A hydrogel
based photonic devices for high-sensitivity glucose sensing, Sensors
and Actuators B: Chemical, 2023,
386:133707. 14.Liang
Zhang, Zizhou Wei, Yichun Li, Haozhe Shou, Han Wang, Mengshi Zhu, Xiang long
Zeng, Wei Chen, Fufei Pang, and Tingyun Wang. Sub-kHz
high-order mode Brillouin random fiber laser based on long-period fiber
grating and distributed Rayleigh scattering in a half-open linear cavity,
Optics Express, 2023,
31(10): 15484-15494. 15.Xiaobo Xue,
Qi Jiang, Fufei Pang*,
Jianxiang Wen, Wei Chen, Xianglong Zeng, Liang Zhang, Heming Wei, and Tingyun
Wang. Low loss side-polished pumping coupler for high order OAM modes
amplification. Optics Express, 2023, 31: 24623-24632. 16.Qi Jiang,
Xiaobo Xue, Fufei Pang*,
Liang Zhang, Mengshi Zhu, Heming Wei, Cheng Du, Wei Li, and Tingyun Wang.
Seven-Ring-Core Erbium-Doped Fiber for OAM-MDM Amplification. IEEE
Photonics Journal, 2023,
15(4): 1-6. 17.Yong Hu,
Heming Wei, Zhangwei Ma, Liang Zhang, Fufei Pang*, and Tingyun Wang.
Microbubble-based optical fiber Fabry-Perot sensor for simultaneous
high-pressure and high-temperature sensing,
Optics Express, 2022,
30(19): 33639-33651. 18.Zhifeng
Wang, Hartmut Bartelt, Zhangwei Ma, Zhenyi Chen, Fufei Pang*, Tingyun Wang. Temperature
Sensing Characteristics of a Four-Core Sapphire Derived Fiber Based on
Supermode Interference, IEEE Sensors Journal, 2022, 22(20): 19366-19377. 19.Zhangwei
Ma, Heming Wei, Liang Zhang, Zhifeng Wang, Zhenyi Chen, Fufei Pang*, Tingyun Wang. Disordered
mullite grains in a sapphire-derived fiber for high-temperature sensing,
Optics Express, 2022,
30(10): 16606-16618. 20.Wei Wei,
Xiao Lu, Fufei Pang*,
Heming Wei, Liang Zhang, and Tingyun Wang. Fabrication and characterization
of low-loss Gaussian-like reversed ridge optical waveguides,
IEEE Photonics Technology Letters, 2022, 34(12): 649-652. 21.Fufei Pang, Lina Xiang, Huanhuan Liu, Liang Zhang, Jianxiang
Wen, Xianglong Zeng, and Tingyun Wang. Review on Fiber-Optic Vortices and
Their Sensing Applications, Journal of Lightwave Technology, 2021, 39(12): 3740-3750. 22.Zhifeng
Wang, Liang Zhang, Zhangwei Ma, Zhenyi Chen, Tingyun Wang, and Fufei
Pang*.
High-Sensitivity Bending Sensor Based on Supermode Interference in Coupled
Four-Core Sapphire-Derived Fiber, Journal
of Lightwave Technology, 2021,
39(12): 3932-3940. 23.Zhangwei
Ma, Jintao Chen, Heming Wei, Liang Zhang, Zhifeng Wang, Zhenyi Chen, Fufei
Pang*, and Tingyun
Wang. Compound Fabry–Pérot interferometer for simultaneous high-pressure and
high-temperature measurement, Optics Express 2021, 29 (15), 24289-24299. 24.Liu,
Zhichao, Zhang, Liang, Wei, Heming, Xiao, Zhelan, Qiu, Zenghuan, Sun, Ruoqi, Pang, Fufei*, Wang, Tingyun.
Underwater acoustic source localization based on phase-sensitive optical time
domain reflectometry, Optics Express, 2021, 29(9): 12880-12892. 25.Ziming
Guo, Huanhuan Liu, Lina Xiang, Lifei Chen, Junfeng Yang, Jianxiang Wen, Yana
Shang, Tingyun Wang, and Fufei
Pang*. Generation of Perfect Vortex Beams With Polymer-Based Phase
Plate, IEEE Photonics Technology Letters, 2020, 32(10): 565-568. 26.Zhen Chen,
Liang Zhang, Huanhuan Liu, Peng Peng, Zhichao Liu, Shi Shen, Na Chen, Shenhui
Zheng, Jian Li, and Fufei Pang*.
3D Printing Technique‐Improved
Phase-Sensitive OTDR for Breakdown Discharge Detection of Gas-Insulated
Switchgear, Sensors, 2020, 20, 1045. 27.Huanhuan
Liu, Zilong Li, Ye Yu, Jincan Lin, Shuaishuai Liu, Fufei Pang* and Tingyun Wang. Nonlinear optical properties
of anisotropic two-dimensional layered materials for ultrafast photonics, Nanophotonics,
2020,
9(7): 1651-1673. 28.Junfeng
Yang, Huanhuan Liu, Jianxiang Wen, Lifei Chen, Yana Shang, Na Chen, Sujuan
Huang, Tingyun Wang, and Fufei
Pang*. Cylindrical vector modes based Mach-Zehnder interferometer
with vortex fiber for sensing applications, Applied
Physics Letters, 2019, 115, 051103. 29.Zhifeng
Wang, Jintao Chen, Heming Wei, Huanhuan Liu, Zhangwei Ma, Na Chen, Zhenyi
Chen, Tingyun Wang, and Fufei Pang*.
Sapphire Fabry–Perot interferometer for high-temperature pressure sensing, Applied
Optics, 2020,
59(17): 5189-5196. 30.Zhifeng
Wang, Huanhuan Liu, Zhangwei Ma, Zhenyi Chen, Ttingyun Wang, and Fufei Pang*. High temperature
strain sensing with alumina ceramic derived fiber based Fabry-Perot
interferometer, Optics Express, 2019, 27(20): 27691-27701. 31.Fufei Pang*, Haoqiang Zheng, Huanhuan Liu, Junfeng Yang, Na
Chen, Yana Shang, Siddharth Ramachandran, and Tingyun Wang. The Orbital
Angular Momentum Fiber Modes for Magnetic Field Sensing, IEEE
Photonics Technology Letters,2019, 31(11): 893-896. 32.Junfeng Yang, Huanhuan Liu, Fufei Pang*, Jianxiang Wen, Haoqiang Zheng, Lifei Chen,
Xinyu He, Yana Shang, Na Chen, Yingchun Li, Tingyun Wang, All-Fiber
Multiplexing and Transmission of High-Order Circularly Polarized Orbital
Angular Momentum Modes With Mode Selective Couplers, IEEE Photonics Journal, 2019, 11(3): 7202909. 33.Huanan Liu, Fufei
Pang*, Ling Hong, Zhangwei Ma, Leilin Huang, Zhifeng Wang, Jianxiang
Wen, Zhenyi Chen, and Tingyun Wang. Crystallization-induced refractive index
modulation on sapphire-derived fiber for ultrahigh temperature sensing, Optics Express, 2019, 27(5): 6201-6209. 34.Huanhuan Liu, Ye Yu, Wei Song, Qiao Jiang, and Fufei Pang*, Recent
development of flat supercontinuum generation in specialty optical fibers, Opto-Electronic Advances, 2019,
2(2): 180020. 35.Zhangwei Ma, Zhifeng Wang, Huanhuan Liu, Fufei Pang*, Zhenyi Chen, and
Tingyun Wang. Tensile strength and failure behavior of bare single mode
fibers, Optical
Fiber Technology, 2019, 52, 101966. 36.Xuanwei
Mei, Fufei Pang*, Huanhuan
Liu, Guoqin Yu, Yuying Shao, Tianyu Qian, Chengbo Mou, Longbao Lv, and
Tingyun Wang. Fast coarse-fine locating method for φ-OTDR, Optics
Express, 2018, 26(3): 2659-2667. 37.Huanhuan
Liu, Fufei Pang*, Longbao
Lv, Xuanwei Mei, Yingxiong Song, Jian Chen, and Tingyun Wang. True Phase
Measurement of Distributed Vibration Sensors Based on Heterodyne ϕ-OTDR,
IEEE Photonics Journal, 2018,
10(1): 7101309. 38.Shuangfeng
Yu, Fufei Pang*,
Huanhuan Liu, Xianjin Li, Junfeng Yang, and Tingyun Wang. Compositing orbital
angular momentum beams in Bi4Ge3O12 crystal for magnetic field sensing, Applied
Physics Letters, 2017,
111, 091107. 39.Lin Hong, Fufei Pang*, Huanhuan
Liu, Jin Xu, Zhenyi Chen, Ziwen Zhao, and Tingyun Wang. Refractive Index
Modulation by Crystallization in Sapphire-Derived Fiber, IEEE
Photonics Technology Letters, 2017, 9:
723-726. 40.Yu
Zhang, Fufei Pang*,
Huanhuan Liu, Xiangqing Jin, Sujuan Huang, Yingchun Li,
Jianxiang Wen, Zhenyi Chen, Min Wang, and Tingyun Wang. Generation of
the First-Order OAM Modes in Ring Fibers by Exerting Pressure Technology, IEEE
Photonics Journal, 2017,
9(2):7101609. 41.Tianyu
Tu, Fufei Pang*, Shan
Zhu, Jianjing Cheng, Huanhuan Liu, Jianxiang Wen, and Tingyun
Wang. Excitation of Bloch surface wave on tapered fiber coated with
one-dimensional photonic crystal for refractive index sensing, Optics Express,
2017, 25(8): 9019-9027. 42.Jin
Xu, Huanhuan Liu, Fufei
Pang*, Ling Hong L, Zhangwei Ma, Ziwen Zhao,
Na Chen, Zhenyi Chen, and Tingyun Wang. Cascaded Mach-Zehnder
interferometers in crystallized sapphire-derived fiber for
temperature-insensitive filters, Optical Materials Express,
2017, 7(4): 1406-1413. 43.Fufei Pang*, Mengting
He, Huanhuan Liu, Xuanwei Mei, Jiaming Tao, Tongzhi
Zhang, Xiaobei Zhang, Na Chen, and Tingyun Wang. A
Fading-Discrimination Method for Distributed Vibration Sensor Using Coherent
Detection of phi-OTDR, IEEE Photonics Technology Letters, 2016,
28(23): 2752-2755. 44.Xiangqing
Jin, Fufei Pang*, Yu
Zhang, Sujuan Huang, Yingchun Li, Jianxiang Wen,
Zhenyi Chen, Ming Wang, and Tingyun Wang. Generation of the
First-Order OAM Modes in Single-Ring Fibers by Offset Splicing Technology, IEEE Photonics Technology
Letters, 2016, 28(14): 1581-1584. 45.Tongzhi
Zhang, Fufei Pang*, Huanhuan
Liu, Jiajing Cheng, Longbao Lv, Xiaobei Zhang, Na Chen, Tingyun
Wang. A Fiber-Optic Sensor for Acoustic Emission Detection in a High Voltage
Cable System, Sensors, 2016, 16(12):2026. 46.Shan Zhu, Fufei Pang*,
Sujuan Huang, Fang Zou, Qiang Guo, Jiangxiang Wen, and Tingyun
Wang. High Sensitivity Refractometer Based on TiO2-Coated Adiabatic Tapered
Optical Fiber via ALD Technology, Sensors, 2016, 16(8):1295. 47.Yanhua
Dong, Jianxiang Wen, Fufei Pang,
Yanhua Luo, Gangding Peng, Zhenyi Chen, and Tingyun Wang. Formation and photoluminescence property of PbS
quantum dots in silica optical fiber based on atomic layer deposition, Optical Materials Express, 2015,
5(4): 712-719. 48.Shan Zhu, Fufei Pang*, Sujuan Huang,
Fang Zou, Yanhua Dong, and Tingyun Wang. High sensitivity refractive index
sensor based on adiabatic tapered optical fiber deposited with nanofilm by
ALD, Optics
Express, 2015,23(11): 13880-13888. 49.Shaolin
Zhang, Ziwen Zhao, Na Chen, Fufei
Pang, Zhenyi Chen, Yunqi Liu, and Tingyun Wang. Temperature characteristics of silicon core
optical fiber Fabry-Perot interferometer, Optics Letters, 2015,
40(7): 1362-1365. 50.Zhenyi
Chen, Zhangmin Dai, Na Chen, Shupeng Liu, Fufei Pang, Bo Lu, and
Tingyun Wang. Gold Nanoparticles-Modified Tapered Fiber Nanoprobe for
Remote SERS Detection, IEEE Photonics Technology Letters, 2014,
26(8): 777-780. 51.Ying Zhao, Fufei Pang*, Yanhua
Dong, Jianxiang Wen, Zhenyi Chen, and Tingyun Wang. Refractive index
sensitivity enhancement of optical fiber cladding mode by depositing nanofilm
via ALD technology, Optics Express, 2013,21(22): 26136- 26143. 52.Hairun Guo, Fufei Pang, Xianglong
Zeng, and Tingyun Wang. Gain characteristics of quantum dot fiber amplifier
based on asymmetric tapered fiber coupler, Optical Fiber Technology, 2013, 19(2):143-147. 53.Hairun Guo, Fufei Pang, Xianglong
Zeng, and Tingyun Wang. PbS quantum dot fiber amplifier based on a tapered
SMF fiber, Optics
Communications, 2012,
285(13-14):3222-3227. 54.Fufei
Pang*, Huanhuan
Liu, Hairun Guo, Yunqi Liu, Xianglong Zeng, Na Chen, Zhenyi Chen, and Tingyun
Wang. In-Fiber Mach-Zehnder Interferometer Based on Double Cladding Fibers
for Refractive Index Sensor, IEEE Sensor Journal, 2011, 11(10): 2395 – 2400. 55.Fufei
Pang*, Xiaolan
Sun, Hairun Guo, Jiwen Yan, Jing Wang, Xianglong Zeng, and Zhenyi Chen,
Tingyun Wang. A PbS quantum dots fiber amplifier excited by evanescent wave, Optics Express, 2010,18(13): 14024-14030. 56.Huanhuan Liu, Fufei Pang*,
Hairui Guo, Wenxin Cao, Yunqi Liu, Na Chen, Zhenyi Chen, and Tingyun Wang.
In-series double cladding fibers for simultaneous refractive index and temperature
measurement, Optics Express, 2010,18(12):
13072-13082. 57.Fufei
Pang*, Huanhuan Liu, Na Chen, Yunqi Liu, Xianglong Zeng, Zhenyi
Chen and Tingyun Wang. Cladding-mode resonance of a double-cladding fiber at
a near modal cut-off wavelength for RI sensing, Measurement Science and
Technology, 2010,21(9):
094028. 58.Fufei
Pang*, Wenbin
Liang, Wenchao Xiang, Na Chen, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang.
Temperature-Insensitivity Bending Sensor Based on Cladding-Mode Resonance of
Special Optical Fiber, IEEE Photonics Technology Letters, 2009, 21(2):76-78. 59.Fufei
Pang*, Huanhuan Liu,
Na Chen, Yunqi Liu, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. In-fiber
Michelson interferometer based on double-cladding fiber for refractive index
sensing, 20th International
Conference on Optical Fibre Sensors, Edinburgh, United kingdom, 2009. 60.Fufei
Pang*, Huanhuan Liu,
Na Chen, Yunqi Liu, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang.
Fiber-optic refractive index sensor based on cladding-mode resonance, 20th International
Conference on Optical Fibre Sensors, Edinburgh, United kingdom, 2009. 61.Fufei
Pang*, Wenchao
Xiang, Hairun Guo, Na Chen, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang.
Special optical fiber for temperature sensing based on cladding-mode
resonance, Optics
Express, 2008,16(17):12967-12972. 62.Fufei
Pang*, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. Fabrication
and characteristics of silica optical fiber doped with InP nano-semiconductor
material. Optical
and Quantum Electronics, 2007(39):975–981. 63.Fufei Pang*, Xiuyou Han, Fenghong Chu, Jianxin
Geng, Haiwen Cai, Ronghui Qu, and Zujie Fang. Sensitivity to alcohols of a
planar waveguide ring resonator fabricated by a sol-gel method. Sensors and Actuators B:
Chemical, 2007, 120(2):610-614. 64.Fufei Pang*, Feng Liu, Xiuyou Han, Haiwen Cai,
Ronghui Qu, and Zujie Fang. Analysis of a second-order
polarization-independent filter made of a single ring resonator and a Sagnac
interferometer. Optics Communications, 2006,
260(2):567-570. 65.Fufei Pang*, Xianglong Zeng, Zhenyi Chen, and
Tingyun Wang. Fabrication and characteristics of optical fiber doped with
nano-semiconductor material. ICMAT 2007 Symposium on
Microstructured and Nanostructured Optical Fibers, July
2007, Singapore,(Invited Paper). 授权发明专利: 1. 庞拂飞,陈锦涛,王廷云,胡勇,马章微,王之凤,张亮,魏鹤鸣, 一种光纤法布里-珀罗密封腔压力传感器及制备方法, 申请日:2021.04.21,授权公布号:CN113188691 B. (已授权) 2. 庞拂飞,黄蕾霖,刘奂奂,陈娜,王廷云,王之凤,陈锦涛,肖磊,一种基于蓝宝石与光纤插芯键合的光纤传感器及制备方法,申请日:2019.05.13,授权公布号:CN110160570 B. (已授权) 3. 庞拂飞,郑浩强,刘奂奂,王廷云,杨俊锋,一种基于单缝检测的光涡旋光纤电流传感器,申请日:2019.03.15,授权公布号:CN109917169 B. (已授权) 4. 庞拂飞,李先进,王廷云,刘奂奂,喻双凤,光涡旋模式全光纤电流传感器,申请日:2017.12.26,授权公布号:CN108593995 B. (已授权) 5. 庞拂飞,李先进,高小庆,刘奂奂,王廷云,邵宇鹰,钱天宇,彭鹏,杨俊锋,复合光涡旋产生方法,申请日:2017.12.26,授权公布号:CN108227220 B. (已授权) 6. 庞拂飞,梅烜玮,刘奂奂,王廷云,吕龙宝,宋英雄,陈健,李迎春,张俊杰,相位敏感光时域反射分布式光纤传感系统精确定位方法,申请日:2017.05.24,授权公布号:CN107167168 B. (已授权) 7. 庞拂飞,梅烜玮,王廷云,吕龙宝,刘奂奂,宋英雄,陈健,李迎春,张俊杰,相位敏感光时域反射分布式光纤传感系统快速定位方法,申请日:2017.05.24,授权公布号:CN107101658 B. (已授权) 8. 庞拂飞,洪琳,王廷云,刘奂奂,徐金,张小贝
陈振宜,基于析晶的光纤法布里-珀罗腔高温传感器及制造方法,申请日:2016.09.19,授权公布号:CN106289339 B. (已授权) 9. 庞拂飞,洪琳,王廷云,刘奂奂,陈娜,徐金,基于纤芯材料析晶的长周期光纤光栅及其制作方法,申请日:2016.09.19,授权公布号:CN106646729 B. (已授权) 10.庞拂飞,洪琳,陈振宜,赵子文,刘奂奂,徐金,王廷云,一种光纤纤芯折射率调制方法,申请日:2016.09.19,授权公布号:CN106477874 B. (已授权) 11.庞拂飞,贺梦婷,梅煊玮,张小贝,王廷云,相位敏感光时域反射光纤传感系统定位方法,申请日:2015.12.16,授权公布号:CN105466548 B. (已授权) 12.庞拂飞,贺梦婷,梅煊玮,陈娜,王廷云,相位敏感光时域反射光纤分布式传感系统相位计算方法,申请日:2015.12.16,授权公布号:CN105509868 B. (已授权) 13.庞拂飞,李明,王廷云,张小贝,郭海润,郭强,陈娜,以高频脉冲二氧化碳激光作为热源的光纤熔融拉锥方法,申请日:2011.03.15,授权公布号:CN102147499 B. (已授权) 14.庞拂飞,王廷云,刘奂奂,陈娜,徐平,闫吉文,向文超,陈振宜,基于同轴光纤的马赫曾德干涉仪,申请日:2009.01.04,授权公布号:CN101464539 B. (已授权) |
|
Professor FuFei Pang,PH.D |
|
Office: |
Room
535, Xiangying Building, Baoshan Campus (east area); B409
B-Building, Baoshan Campus(east area), Shanghai University |
|
Mail Address(Zip Code): |
No.333 Nanchen Road, Baoshan, Shanghai 200444
P.R.China |
|
Phone: |
86-21-66136329 |
|
Email: |
ffpang@shu.edu.cn |
|
URL: |
||
BIOGRAPHY: Pang Fufei, professor, was funded by
the Outstanding Youth Fund of the National Natural Science Foundation of
China in 2014. From Sep. 2001 to Jun. 2006, he studied for a Ph.D. in
Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences
(master-doctoral co-study). In July 2006, he joined the School of
Communication and Information Engineering of Shanghai University as a
scientific researcher and teacher. Supported by the key laboratory of
specialty optical fiber and optical access networks (Ministry of Science and
Technology-Shanghai Government), he engaged in research work on special
optical fiber devices, optical fiber sensing, optical fiber communications,
etc. From Jul. 2010 to Jun. 2011, he worked at the Optical Fiber Research
Center of the University of New South Wales (UNSW) as visiting scholar
awarded by China Scholarship Council (CSC). Currently, he has published more
than 200 academic papers, of which more than 100 have been indexed by SCI;
applied for 50 invention patents, of which 30 have been authorized. He has
presided over 2 key project of the National Natural Science Foundation of
China, 2 national key research and development projects,1 sub project of the
National Major Scientific Instrument Project, key scientific research
projects of the province and ministry, and projects entrusted by enterprises
meanwhile. He has been funded by Shanghai “Shuguang Program”, “Rising-Star
Program”, "Chenguang Program" and "Talent Development
Fund". He was awarded the "Shanghai Youth May 4th Medal" in
2013, Shanghai "Education Talent Award" in 2014. In 2022, he won the
first prize of Shanghai Teaching Achievement Award. In 2024, he won the second
prize for teaching achievements from the Instrumentation Society. In 2022, he
won the first prize of Shanghai Science and Technology Progress Award, and
the first prize of China Optical Engineering Society Science and Technology
Progress Award. Education and Professional Experiences: June, 2013-present,
Professor, School of Communication and Information Engineering, Shanghai
University June, 2008-May
2013, Associate Professor, School of Communication and Information
Engineering, Shanghai University July,
2010- July, 2011, Visiting Scholar awarded by China Scholarship Council (CSC)
in University of New South Wales (UNSW), Australia June, 2006-May
2008, Lecturer, School of Communication and Information Engineering, Shanghai
University September,
2001- June, 2006, Ph.D. in Optical Engineering, Shanghai Institute of Optics
and Fine Mechanics, CAS, Shanghai Research Interests: 1.
Fiber optic sensors and fiber
optic communication technology; 2.
Integrated optical
waveguide technology; 3.
Design and fabrication
process of special optical fibers. ACADEMIC HONOR: In
2024, won the second prize for teaching achievements from the Instrumentation
Society. In
2022, won the first prize of Shanghai Teaching Achievement Award. In
2022, won the first prize of Shanghai Science and Technology Process Award. In
2019, won the second prize of Shanghai Science and Technology Process Award. In
2017, won the second prize of Science and Technology Process of State Grid
Shanghai Electric Power Company. In
2016, awarded the title of “ShuGuang Scholar” in Shanghai. In
2016, won the Shanghai Talent Development Fund Award. In
2014, funded by the “Outstanding Youth” Fund of National Natural Science
Foundation of China. In
2013, won the third prize of Shanghai Technical Invention. In
2010, funded by the Shanghai
“Rising-Star Program” Project. In 2007, awarded the
first “ChenGuang Program” talent fund of Shanghai Education Development Fund. ACADEMIC PART-TIME JOB: Ø
The reviewer of《Nature Communications》、《Scientific Reports》、《Sensor and Actuator B: Chemical》、《IEEE Journal of Lightwave Technology》、《IEEE Photonics Technology Letters》、《Optics Express》(SCI Journal) REsearch projects:
1. National Key Research and Development
Program Project, “Design,
manufacturing, and sensor packaging of MEMS fiber optic vibration sensitive
components” (2023YFB3209502),
2023-2026, PI
2. Joint Key
Fund Project of the National Natural Science Foundation of China, “Optical
interconnect waveguide and its optical coupling technology” (U224137), 2023.01-2026.12, PI
3. National Key
Research and Development Program, “Optical interconnect
waveguide and its optical coupling technology” (2019YFB1802901), 2020-2023, PI
4. Natural Science Foundation
of China, “Research on the key technology of optical vortex mode fiber
current sensor” (61975108), 2020.01-2023.12, PI
5. Natural Science Foundation
of China, “Key fabrication technology of single-core multichannel
long-distance transmission optical vortex fiber” (61635006), 2017.01-2021.12,
PI
6. National
Key Research and Development Program, “Research on microstructure design and packaging
technology of optical fiber sensor” (2016YFF0100603), 2016-2018, PI
7. Natural Science Foundation
of China, “Special optical fiber materials and technologies” (61422507),2015.01-2017.12, PI
8. Key
Project of Science and Technology Commission of Shanghai Municipality,
“Research on monitoring technology of optical fiber sensing for power cable
bureau” (14DZ1201403), 2014.07-2016.06,
PI
9. Key
Project of Science and Technology Commission of Shanghai Municipality,
“Research on intelligent internet of Things technology for Large photovoltaic
power station cluster” (14511105602), 2014.07-2016.06, PI 10. Key Project of Shanghai
Education Committee, “Research on the theory and technology of optical
printed circuit board interconnect” (14ZZ093), 2014.1-2016.12, PI 11. Key Project of Science
and Technology Commission of Shanghai Municipality, “Coherent optical time
domain reflectometry of optical fiber sensing technology for safety
monitoring in electrical power system” (13510500300), 2013.06-2015.06, PI 12. Natural Science Foundation of China, “Research on the diluted magnetic
semiconductor quantum dot doped silica magneto-optic optical fiber” (61275090), 2013.01-2016.12, PI 13. Shanghai “Rising-Star
Program” Project, “Research on the key technologies of refractive index and
temperature dual-parameter sensor based on cladding mode resonant special
fibers” (10QA1402600), 2010-2012, PI 14. Natural Science Foundation of China, “Research on sensing mechanics of the
cladding-mode resonant special fiber with temperature insensitivity” (60807031), 2009-2011, PI 15. Project of Shanghai Education Committee, “Research
on integrated optical waveguide quantum dots amplifier excited by evanescent
wave” (10YZ12), 2010.01-2011.12, PI 16. Shanghai “ChenGuang
Program” Project, “Research on the fabrication technique of the cladding-mode
resonant specialty optical fiber” (2007CG54), 2007-2009, PI Teaching Courses: Ø Fundamental electric and
electronic circuits (for undergraduates); Intelligent optical fiber, sense
the world (for freshman); Progress in communication and information
technology (for graduate). Research Students Supervision: Ø Graduated
Ph.D. Students: Junfeng Yang (2015); Zhangwei Ma (2016); Zhifeng Wang (2018). Ø Graduated
Master's Students: Wenbin Liang (2006); Huanhuan Liu (2007); Lungang Liu,
Jian Zhang (2008); Lugang Lan, Ting Zhou (2009); Shiqiong Chen, Libo Wu
(2010); Xiao Ma, Li Chen, Ying Zhao (2011); Hui Xu, Yebin Feng, Xin Gu
(2012); Mengting He, Pengfei Chen, Lili Guo(2013); Lin Hong, Tongzhi Zhang,
Tianyu Tu, Jianhui Wang (2014); Jin Xu, Xinajin Li, Longbao Lv (2015); Leilin
Huang, Lei Xiao, Haoqiang Zheng, Luchuan Li (2016); Zhen Chen, Shi Shen, Ziming
Guo, Yaqing Li (2017); Jintao Chen, Zhichao Liu, Hao Wu, Lina Xiang (2018); Jianheng
Qiu, Pengchong Wang, Wei Wei, Shuaishuai Liu, Ruoqi Sun (2019); Xiao Lu,
Xiaobo Xue, Qi Jiang, Yong Hu, Qiao Cao (2020); Yunzhe Gu, Xingyu Xu, Yi Tang, Yi Yang (2021). Ø PhD
Candidates: Lifei Chen (2017); Lina Xiang (2020); Jing Wen (2021); Xian Wang
(2023); Xuecheng Liu (2024); Ø Postgraduate
Students: Yunzhe Gun, Xingyun Xu, Yi Tang, Yi Yang (2021); Xueli Chen, Luo
Chen, Heng Guo, Junjie Zhu (2022); Xingkui Pang, Yue Xin, Xiaoyu Yan (2023). Ø Huanhuan
Liu’s master’s thesis was awarded as “2011 Shanghai Graduate Excellent
Achievement (academic dissertation)”. Ø Ying
Zhao’s master’s thesis was awarded as “2015 Shanghai Graduate Excellent
Achievement (academic dissertation)”. SELECTED PUBLICATIONS & PUBLIC PRESENTATIONS: 1. Xingyu
Xu, Xiao Lu, Fufei Pang*,
Na Chen, Heming Wei, Liang Zhang, Qianwu Zhang, Tingyun Wang. Overcoming
oxygen inhibition in UV photolithography for the fabrication of low-loss
polymer waveguides, Optics Letters, 2024, 49(9):
2369-2372. 2. Lina
Xiang, Fufei Pang*,
Zhongyin Xiao, Liang Zhang, Heming Wei, Mengshi Zhu, Siddharth Ramachandran, Tingyun Wang. Vibration-insensitive polarimetric
fiber optic current sensor based on orbital angular momentum modes in an
air-core optical fiber, Optics Letters, 2024, 49(7):
1753-1756. 3. Liang
Zhang*, Haozhe Shou, Yiyang
Feng, Zhengxuan Li, Mengshi Zhu, Heming
Wei, Yingxiong Song, Fufei Pang*, Tingyun
Wang. Self-injection locked
low-noise Brillouin random fiber laser via dynamic fiber grating for QAM
coherent communication, Applied Physics Letters,
2024, 124(13):
131104. 4. Yi
Tang, Mengshi Zhu, Fufei
Pang*,
Heming Wei, Liang Zhang, Wei Chen, Tingyun
Wang. Distributed optical fiber
magnetic field sensor based on polarization-sensitive OFDR,
Optics Express,
2024, 32(7):
11726-11736. 5. Yunzhe
Gu, Fufei Pang*,
Mengshi Zhu, Yi
Tang, Yi Tang, Liang Zhang, Heming Wei, Tingyun Wang. Heterogeneous integrated optical fiber with side
nickel core for distributed magnetic field sensing, Optics Express,
2024, 32(5):
7540-7552. 6. Liang
Zhang*, Han Wang, Yichun Li,
Song Gao, Mengshi Zhu, Heming
Wei, Fufei Pang*,
Tingyun Wang. Towards high-sensitivity and high-accuracy forward
Brillouin scattering-based optomechanical temperature sensing in
thin-diameter fibers, Optics Express, 2024, 32(1):
586-598. 7. Heming
Wei, Zhangli Wu, Yan Wei, Chen Wang, Haiyan Zhang, Fufei Pang*, Carlos Marques, Christophe
Caucheteur, and Xuehao Hu. 3D printed Fabry-Perot acoustic probe with a glass
horn tube, Optics and Laser
Technology, 2024, 168: 109977. 8. Liang
Zhang*, Jilin Zhang, Fufei
Pang*, Tingyun Wang,
Liang Chen, Xiaoyi Bao. Transient replica symmetry breaking in Brillouin
random fiber lasers, PhotoniX, 2023, 4(1): 33. 9. Heming
Wei, Zhangli Wu, Kexuan Sun, Haiyan Zhang, Chen Wang, Keming Wang, Tian Yang,
Fufei Pang*,
Xiaobei Zhang, Yingyun Wang, and Sridhar Krishnaswamy. Two-photon 3D printed
spring-based Fabry-Pérot cavity resonator for acoustic wave detection and
imaging, Photonics Research,
2023, 11(5):
780-786. 10. Yan
Wei, Kexuan Sun, Heming Wei, Mengshi Zhu, Fufei Pang, Carlos
Marques, and Xuehao Hu. A Corrugated Diaphragm-Based Fabry-Perot Ultrasonic
Sensor by Two-Photon 3D Printing, IEEE Photonics Technology Letters, 2023,
35(20): 1078-1081. 11. Pengchong
Wang, Mengshi Zhu, Fufei Pang*, Heming Wei, Liang Zhang, Yana Shang, Wei Chen, and
Tingyun Wang. Cylindrical Vector Beams for Alternating Magnetic Field Sensing
Based on YIG Crystal, IEEE Photonics Technology Letters, 2023,
35(19), 1031-1034. 12. Heming
Wei, Kexuan Sun, Yan Wei, Mengshi Zhu, Haiyan Zhang, Fufei Pang,
Tingyun Wang, and Sridhar Krishnaswamy. Micro-3D printed Concanavalin A
hydrogel based photonic devices for high-sensitivity glucose sensing, Optics Letters,
2023, 48(16): 4412-4415. 13. Heming
Wei, Long Han, Ruixue Yin, Tian Yang, Yunqi Liu, Chengbo Mou, Fufei
Pang, and Wang, Tingyun. Micro-3D printed Concanavalin A hydrogel
based photonic devices for high-sensitivity glucose sensing, Sensors and Actuators B:
Chemical, 2023, 386:133707. 14. Liang
Zhang, Zizhou Wei, Yichun Li, Haozhe Shou, Han Wang, Mengshi Zhu, Xiang long
Zeng, Wei Chen, Fufei Pang, and Tingyun Wang. Sub-kHz
high-order mode Brillouin random fiber laser based on long-period fiber
grating and distributed Rayleigh scattering in a half-open linear cavity, Optics Express,
2023, 31(10): 15484-15494. 15. Xiaobo
Xue, Qi Jiang, Fufei Pang*,
Jianxiang Wen, Wei Chen, Xianglong Zeng, Liang Zhang, Heming Wei, and Tingyun
Wang. Low loss side-polished pumping coupler for high order OAM modes
amplification. Optics Express, 2023, 31: 24623-24632. 16. Qi
Jiang, Xiaobo Xue, Fufei Pang*, Liang Zhang, Mengshi Zhu, Heming Wei, Cheng Du, Wei Li,
and Tingyun Wang. Seven-Ring-Core Erbium-Doped Fiber for OAM-MDM
Amplification. IEEE Photonics Journal, 2023,
15(4): 1-6. 17. Yong
Hu, Heming Wei, Zhangwei Ma, Liang Zhang, Fufei Pang*, and Tingyun Wang.
Microbubble-based optical fiber Fabry-Perot sensor for simultaneous
high-pressure and high-temperature sensing, Optics Express,
2022, 30(19): 33639-33651. 18. Zhifeng
Wang, Hartmut Bartelt, Zhangwei Ma, Zhenyi Chen, Fufei Pang*, Tingyun Wang. Temperature
Sensing Characteristics of a Four-Core Sapphire Derived Fiber Based on
Supermode Interference, IEEE Sensors Journal, 2022,
22(20): 19366-19377. 19. Zhangwei
Ma, Heming Wei, Liang Zhang, Zhifeng Wang, Zhenyi Chen, Fufei Pang*, Tingyun Wang. Disordered
mullite grains in a sapphire-derived fiber for high-temperature sensing, Optics Express,
2022, 30(10): 16606-16618. 20. Wei
Wei, Xiao Lu, Fufei Pang*,
Heming Wei, Liang Zhang, and Tingyun Wang. Fabrication and characterization
of low-loss Gaussian-like reversed ridge optical waveguides, IEEE Photonics
Technology Letters, 2022, 34(12): 649-652. 21. Fufei
Pang, Lina Xiang, Huanhuan Liu, Liang Zhang, Jianxiang
Wen, Xianglong Zeng, and Tingyun Wang. Review on Fiber-Optic Vortices and
Their Sensing Applications, Journal of Lightwave Technology, 2021,
39(12): 3740-3750. 22. Zhifeng
Wang, Liang Zhang, Zhangwei Ma, Zhenyi Chen, Tingyun Wang, and Fufei
Pang*.
High-Sensitivity Bending Sensor Based on Supermode Interference in Coupled
Four-Core Sapphire-Derived Fiber, Journal of Lightwave Technology, 2021,
39(12): 3932-3940. 23. Zhangwei
Ma, Jintao Chen, Heming Wei, Liang Zhang, Zhifeng Wang, Zhenyi Chen, Fufei
Pang*, and Tingyun
Wang. Compound Fabry–Pérot interferometer for simultaneous high-pressure and
high-temperature measurement, Optics Express 2021, 29 (15),
24289-24299. 24. Liu,
Zhichao, Zhang, Liang, Wei, Heming, Xiao, Zhelan, Qiu, Zenghuan, Sun, Ruoqi, Pang, Fufei*, Wang, Tingyun.
Underwater acoustic source localization based on phase-sensitive optical time
domain reflectometry, Optics Express, 2021, 29(9): 12880-12892. 25. Ziming
Guo, Huanhuan Liu, Lina Xiang, Lifei Chen, Junfeng Yang, Jianxiang Wen, Yana
Shang, Tingyun Wang, and Fufei
Pang*. Generation of Perfect Vortex Beams With Polymer-Based Phase
Plate, IEEE Photonics Technology
Letters, 2020, 32(10): 565-568. 26. Zhen
Chen, Liang Zhang, Huanhuan Liu, Peng Peng, Zhichao Liu, Shi Shen, Na Chen,
Shenhui Zheng, Jian Li, and Fufei
Pang*. 3D Printing Technique‐Improved Phase-Sensitive OTDR for
Breakdown Discharge Detection of Gas-Insulated Switchgear, Sensors,
2020, 20, 1045. 27. Huanhuan
Liu, Zilong Li, Ye Yu, Jincan Lin, Shuaishuai Liu, Fufei Pang* and Tingyun Wang. Nonlinear optical properties
of anisotropic two-dimensional layered materials for ultrafast photonics, Nanophotonics, 2020,
9(7): 1651-1673. 28. Junfeng
Yang, Huanhuan Liu, Jianxiang Wen, Lifei Chen, Yana Shang, Na Chen, Sujuan
Huang, Tingyun Wang, and Fufei
Pang*. Cylindrical vector modes based Mach-Zehnder interferometer
with vortex fiber for sensing applications, Applied Physics Letters, 2019,
115, 051103. 29. Zhifeng
Wang, Jintao Chen, Heming Wei, Huanhuan Liu, Zhangwei Ma, Na Chen, Zhenyi
Chen, Tingyun Wang, and Fufei Pang*.
Sapphire Fabry–Perot interferometer for high-temperature pressure sensing, Applied Optics,
2020, 59(17): 5189-5196. 30. Zhifeng
Wang, Huanhuan Liu, Zhangwei Ma, Zhenyi Chen, Ttingyun Wang, and Fufei Pang*. High temperature
strain sensing with alumina ceramic derived fiber based Fabry-Perot
interferometer, Optics Express, 2019, 27(20): 27691-27701. 31. Fufei Pang*,
Haoqiang Zheng, Huanhuan Liu, Junfeng Yang, Na Chen, Yana Shang, Siddharth
Ramachandran, and Tingyun Wang. The Orbital Angular Momentum Fiber Modes for
Magnetic Field Sensing, IEEE Photonics Technology Letters,2019,
31(11): 893-896. 32. Junfeng
Yang, Huanhuan Liu, Fufei Pang*,
Jianxiang Wen, Haoqiang Zheng, Lifei Chen, Xinyu He, Yana Shang, Na Chen,
Yingchun Li, Tingyun Wang, All-Fiber Multiplexing and Transmission of
High-Order Circularly Polarized Orbital Angular Momentum Modes With Mode
Selective Couplers, IEEE Photonics Journal,
2019, 11(3): 7202909. 33. Huanan
Liu, Fufei Pang*, Ling
Hong, Zhangwei Ma, Leilin Huang, Zhifeng Wang, Jianxiang Wen, Zhenyi Chen,
and Tingyun Wang. Crystallization-induced refractive index modulation on
sapphire-derived fiber for ultrahigh temperature sensing, Optics Express, 2019,
27(5): 6201-6209. 34. Huanhuan
Liu, Ye Yu, Wei Song, Qiao Jiang, and Fufei
Pang*, Recent development of flat supercontinuum generation in
specialty optical fibers, Opto-Electronic Advances, 2019,
2(2): 180020. 35. Zhangwei
Ma, Zhifeng Wang, Huanhuan Liu, Fufei
Pang*, Zhenyi Chen, and Tingyun Wang. Tensile strength and failure
behavior of bare single mode fibers, Optical Fiber Technology,
2019, 52, 101966. 36. Xuanwei
Mei, Fufei Pang*, Huanhuan
Liu, Guoqin Yu, Yuying Shao, Tianyu Qian, Chengbo Mou, Longbao Lv, and
Tingyun Wang. Fast coarse-fine locating method for φ-OTDR, Optics Express,
2018, 26(3): 2659-2667. 37. Huanhuan
Liu, Fufei Pang*, Longbao
Lv, Xuanwei Mei, Yingxiong Song, Jian Chen, and Tingyun Wang. True Phase
Measurement of Distributed Vibration Sensors Based on Heterodyne ϕ-OTDR, IEEE Photonics Journal,
2018, 10(1): 7101309. 38. Shuangfeng
Yu, Fufei Pang*,
Huanhuan Liu, Xianjin Li, Junfeng Yang, and Tingyun Wang. Compositing orbital
angular momentum beams in Bi4Ge3O12 crystal for magnetic field sensing, Applied Physics Letters,
2017, 111, 091107. 39. Lin
Hong, Fufei Pang*,
Huanhuan Liu, Jin Xu, Zhenyi Chen, Ziwen Zhao, and Tingyun
Wang. Refractive Index Modulation by Crystallization in Sapphire-Derived
Fiber, IEEE Photonics
Technology Letters, 2017, 9: 723-726. 40. Yu
Zhang, Fufei Pang*,
Huanhuan Liu, Xiangqing Jin, Sujuan Huang, Yingchun Li,
Jianxiang Wen, Zhenyi Chen, Min Wang, and Tingyun Wang. Generation of
the First-Order OAM Modes in Ring Fibers by Exerting Pressure Technology, IEEE Photonics Journal, 2017,
9(2):7101609. 41. Tianyu Tu, Fufei Pang*, Shan Zhu, Jianjing Cheng, Huanhuan
Liu, Jianxiang Wen, and Tingyun Wang. Excitation of Bloch surface
wave on tapered fiber coated with one-dimensional photonic crystal for
refractive index sensing, Optics Express, 2017, 25(8): 9019-9027. 42. Jin
Xu, Huanhuan Liu, Fufei
Pang*, Ling Hong L, Zhangwei Ma, Ziwen Zhao,
Na Chen, Zhenyi Chen, and Tingyun Wang. Cascaded Mach-Zehnder
interferometers in crystallized sapphire-derived fiber for
temperature-insensitive filters, Optical Materials Express, 2017,
7(4): 1406-1413. 43. Fufei Pang*, Mengting
He, Huanhuan Liu, Xuanwei Mei, Jiaming Tao, Tongzhi
Zhang, Xiaobei Zhang, Na Chen, and Tingyun Wang. A
Fading-Discrimination Method for Distributed Vibration Sensor Using Coherent
Detection of phi-OTDR, IEEE Photonics Technology Letters, 2016, 28(23): 2752-2755. 44. Xiangqing Jin, Fufei Pang*, Yu Zhang, Sujuan
Huang, Yingchun Li, Jianxiang Wen, Zhenyi Chen, Ming Wang, and
Tingyun Wang. Generation of the First-Order OAM Modes in Single-Ring Fibers
by Offset Splicing Technology, IEEE Photonics Technology Letters, 2016, 28(14): 1581-1584. 45. Tongzhi
Zhang, Fufei Pang*, Huanhuan
Liu, Jiajing Cheng, Longbao Lv, Xiaobei Zhang, Na Chen, Tingyun
Wang. A Fiber-Optic Sensor for Acoustic Emission Detection in a High Voltage
Cable System, Sensors, 2016, 16(12):2026. 46. Shan
Zhu, Fufei Pang*,
Sujuan Huang, Fang Zou, Qiang Guo, Jiangxiang Wen, and Tingyun
Wang. High Sensitivity Refractometer Based on TiO2-Coated Adiabatic Tapered
Optical Fiber via ALD Technology, Sensors, 2016, 16(8):1295. 47. Yanhua Dong, Jianxiang Wen, Fufei Pang, Yanhua Luo, Gangding Peng, Zhenyi Chen, and Tingyun Wang. Formation and
photoluminescence property of PbS quantum dots in silica optical fiber based
on atomic layer deposition, Optical Materials Express, 2015, 5(4): 712-719. 48. Shan Zhu, Fufei
Pang*, Sujuan Huang, Fang Zou, Yanhua Dong, and Tingyun Wang. High
sensitivity refractive index sensor based on adiabatic tapered optical fiber
deposited with nanofilm by ALD, Optics Express,
2015,23(11):
13880-13888. 49. Shaolin Zhang, Ziwen Zhao, Na Chen, Fufei Pang, Zhenyi Chen, Yunqi
Liu, and Tingyun Wang.
Temperature characteristics of silicon core optical fiber Fabry-Perot
interferometer, Optics Letters,
2015, 40(7): 1362-1365. 50. Zhenyi Chen, Zhangmin Dai, Na Chen, Shupeng Liu, Fufei Pang, Bo Lu, and Tingyun Wang. Gold
Nanoparticles-Modified Tapered Fiber Nanoprobe for Remote SERS Detection,
IEEE Photonics Technology Letters,
2014, 26(8): 777-780. 51. Ying Zhao, Fufei
Pang*, Yanhua Dong, Jianxiang Wen, Zhenyi Chen, and
Tingyun Wang. Refractive index sensitivity enhancement of optical fiber
cladding mode by depositing nanofilm via ALD technology, Optics
Express, 2013,21(22): 26136- 26143. 52. Hairun Guo, Fufei
Pang, Xianglong Zeng, and Tingyun Wang. Gain characteristics of
quantum dot fiber amplifier based on asymmetric tapered fiber coupler, Optical
Fiber Technology,
2013, 19(2):143-147. 53. Hairun Guo, Fufei
Pang, Xianglong Zeng, and Tingyun Wang. PbS quantum dot fiber
amplifier based on a tapered SMF fiber, Optics
Communications,
2012, 285(13-14):3222-3227. 54. Fufei Pang*, Huanhuan Liu, Hairun
Guo, Yunqi Liu, Xianglong Zeng, Na Chen, Zhenyi Chen, and Tingyun Wang.
In-Fiber Mach-Zehnder Interferometer Based on Double Cladding Fibers for
Refractive Index Sensor, IEEE Sensor Journal, 2011, 11(10): 2395 –
2400. 55. Fufei Pang*, Xiaolan Sun, Hairun
Guo, Jiwen Yan, Jing Wang, Xianglong Zeng, and Zhenyi Chen, Tingyun Wang. A
PbS quantum dots fiber amplifier excited by evanescent wave, Optics
Express, 2010,18(13): 14024-14030. 56. Huanhuan Liu, Fufei
Pang*, Hairui Guo, Wenxin Cao, Yunqi Liu, Na Chen, Zhenyi
Chen, and Tingyun Wang. In-series double cladding fibers for simultaneous
refractive index and temperature measurement, Optics
Express,
2010,18(12): 13072-13082. 57. Fufei Pang*, Huanhuan Liu, Na Chen, Yunqi Liu, Xianglong Zeng, Zhenyi Chen and Tingyun Wang.
Cladding-mode resonance of a double-cladding fiber at a near modal cut-off
wavelength for RI sensing, Measurement Science and Technology,
2010,21(9): 094028. 58. Fufei Pang*, Wenbin Liang, Wenchao
Xiang, Na Chen, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang.
Temperature-Insensitivity Bending Sensor Based on Cladding-Mode Resonance of
Special Optical Fiber, IEEE Photonics Technology Letters,
2009,
21(2):76-78.s 59. Fufei Pang*, Huanhuan Liu, Na Chen,
Yunqi Liu, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. In-fiber Michelson
interferometer based on double-cladding fiber for refractive index sensing, 20th
International Conference on Optical Fibre Sensors, Edinburgh, United
kingdom, 2009. 60. Fufei Pang*, Huanhuan Liu, Na Chen,
Yunqi Liu, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. Fiber-optic
refractive index sensor based on cladding-mode resonance, 20th
International Conference on Optical Fibre Sensors, Edinburgh, United
kingdom, 2009. 61. Fufei Pang*, Wenchao Xiang, Hairun
Guo, Na Chen, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. Special optical
fiber for temperature sensing based on cladding-mode resonance, Optics
Express, 2008,16(17):12967-12972. 62. Fufei Pang*, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. Fabrication
and characteristics of silica optical fiber doped with InP nano-semiconductor
material. Optical and Quantum Electronics, 2007(39):975–981. 63. Fufei
Pang*, Xiuyou Han, Fenghong Chu, Jianxin Geng, Haiwen
Cai, Ronghui Qu, and Zujie Fang. Sensitivity to alcohols of a planar
waveguide ring resonator fabricated by a sol-gel method. Sensors
and Actuators B: Chemical, 2007, 120(2):610-614. 64. Fufei
Pang*, Feng Liu, Xiuyou Han, Haiwen Cai, Ronghui Qu, and
Zujie Fang. Analysis of a second-order polarization-independent filter made
of a single ring resonator and a Sagnac interferometer. Optics
Communications, 2006,
260(2):567-570. 65. Fufei
Pang*, Xianglong Zeng, Zhenyi Chen, and Tingyun Wang. Fabrication
and characteristics of optical fiber doped with nano-semiconductor material. ICMAT
2007 Symposium on Microstructured and Nanostructured Optical Fibers,
July 2007, Singapore,(Invited
Paper). Authorized Invention Patents: 1. Pang Fufei, Chen Jintao, Wang Tingyun, Hu
Yong, Ma Zhangwei, Wang Zhifeng, Zhang Liang, Wei Heming. A Fiber Optic Fabry
Perot Sealed Cavity Pressure Sensor and Its Preparation Method, Application
date: April 21, 2021, Authorized publication number: CN113188691 B. (Authorized) 2. Pang Fufei, Huang Leilin, Liu Huanhuan,
Chen Na, Wang Tingyun, Wang Zhifeng, Chen Jintao, Xiao Lei. A Fiber Optic
Sensor and Preparation Method Based on Sapphire and Fiber Plug Bonding,
Application Date: May 13, 2019, Authorization Publication Number: CN110160570
B. (Authorized) 3. Pang Fufei, Zheng Haoqiang, Liu Huanhuan,
Wang Tingyun, Yang Junfeng. a single slit detection based optical vortex
fiber current sensor, Application date: March 15, 2019, Authorized
publication number: CN109917169 B. (Authorized) 4. Pang Fufei, Li Xianjin, Wang Tingyun, Liu
Huanhuan, Yu Shuangfeng. Optical Vortex Mode All Fiber Current Sensor,
Application Date: December 26, 2017, Authorization Publication Number:
CN108593995 B. (Authorized) 5. Pang Fufei, Li Xianjin, Gao Xiaoqing,
Liu Huanhuan, Wang Tingyun, Shao Yuying, Qian Tianyu, Peng Peng, Yang
Junfeng. Method for Generating Composite Light Vortex, Application Date:
December 26, 2017, Authorization Publication Number: CN108227220 B. (Authorized) 6. Pang Fufei, Mei Xuanwei, Liu Huanhuan,
Wang Tingyun, Lv Longbao, Song Yingxiong, Chen Jian, Li Yingchun, Zhang
Junjie. Accurate positioning method for phase sensitive time-domain
reflection distributed fiber optic sensing system, Application date: May 24,
2017, Authorized publication number: CN107167168 B. (Authorized) 7. Pang Fufei, Mei Xuanwei, Wang Tingyun, Lv
Longbao, Liu Huanhuan, Song Yingxiong, Chen Jian, Li Yingchun, Zhang Junjie.
Phase sensitive time-domain reflection distributed fiber optic sensing system
fast positioning method, Application date: May 24, 2017, Authorized
publication number: CN107101658 B. (Authorized) 8. Pang Fufei, Hong Lin, Wang Tingyun, Liu
Huanhuan, Xu Jin, Zhang Xiaobei, Chen Zhenyi. Fiber Optic Fabry Perot Cavity
High Temperature Sensor and Manufacturing Method Based on Crystallization,
Application Date: September 19, 2016, Authorization Publication Number: CN106289339
B. (Authorized) 9. Pang Fufei, Hong Lin, Wang Tingyun, Liu
Huanhuan, Chen Na, Xu Jin. Long period fiber grating based on fiber core
material crystallization and its production method, Application date:
September 19, 2016, Authorized publication number: CN106646729 B. (Authorized) 10. Pang Fufei, Hong Lin, Chen Zhenyi, Zhao
Ziwen, Liu Huanhuan, Xu Jin, Wang Tingyun. A Fiber Optic Core Refractive
Index Modulation Method, Application Date: September 19, 2016, Authorization
Publication Number: CN106477874 B. (Authorized) 11. Pang Fufei, He Mengting, Mei Xuanwei,
Zhang Xiaobei, Wang Tingyun. Phase sensitive time-domain reflection fiber
optic sensing system positioning method, Application date: December 16, 2015,
Authorized publication number: CN105466548 B. (Authorized) 12. Pang Fufei, He Mengting, Mei Xuanwei,
Chen Na, Wang Tingyun. Phase Calculation Method for Phase Sensitive Time
Domain Reflective Fiber Optic Distributed Sensing System, Application Date:
December 16, 2015, Authorization Publication Number: CN105509868 B. (Authorized) 13. Pang Fufei, Li Ming, Wang Tingyun, Zhang
Xiaobei, Guo Hairun, Guo Qiang, Chen Na. Fiber Melting Tapering Method Using
High Frequency Pulse Carbon Dioxide Laser as a Heat Source, Application Date:
March 15, 2011, Authorization Publication Number: CN102147499 B. (Authorized) 14. Pang Fufei, Wang Tingyun, Liu Huanhuan,
Chen Na, Xu Ping, Yan Jiwen, Xiang Wenchao, Chen Zhenyi. Mach Zehnder
interferometer based on coaxial optical fiber, Application date: January 4th,
2009, Authorized publication number: CN101464539 B. (Authorized) |