王鹏飞部门：理学院

学科：光学工程

职务：

职称：教授

指导
资格：博士生导师
电话：**

传真：

邮箱：pwang@hrbeu.edu.cn

邮编：150001

地址：哈尔滨市南岗区南通大街145号哈尔滨工程大学理学楼112室
个人简介
　　王鹏飞，博士，男，1977年7月生，汉族，教授，博士生导师。于2008年11月博士毕业于爱尔兰都柏林理工学院，获光学工程博士学位。2004年5月受意大利外交部、欧航局和联合国教科文组织资助，工作于意大利科研理事会微电子与微系统研究所；2009年1月至2010年8月，获爱尔兰政府EMPOWER博士后奖学金，工作于都柏林理工学院光子学研究中心；2010年8月至2013年8月，获欧盟玛丽居里夫人学者奖学金，工作于英国南安普顿大学光电子研究中心。2013年1月在爱尔兰都柏林理工学院获聘高级研究员职位（终身职位）。SPIE会员、美国光学学会会员、欧盟玛丽居里夫人学会终身会员。

教育经历
2008年11月博士毕业于爱尔兰都柏林理工学院，获光学工程博士学位。

工作经历
1. 2004-2005年工作于意大利科研理事会微电子与微系统研究所；
2. 2005-2008年在爱尔兰都柏林理工学院光子研究中心攻读博士学位；
3. 2009-2010年，获爱尔兰政府EMPOWER博士后奖学金，工作于都柏林理工学院光子研究中心；
4. 2010-2013年，获欧盟居里夫人学者奖学金资助，工作于英国南安普顿大学光电子研究中心；
5. 2013年-2015年，工作于都柏林理工学院光子研究中心；2013年1月获聘爱尔兰都柏林理工学院高级研究员职位（终身教职）；
6. 2015年9月全职回国工作。

研究方向
　　中红外波段光纤激光器、特种光学玻璃材料、光纤传感器件、微纳光纤光子学器件和集成光学光子学器件。　

承担项目
国内工作：目前主持在研科技部国际合作重点专项1项、国家自然科学基金面上项目1项、黑龙江省自然科学基金重点项目1项、人社部归国留学人员基金重点项目1项，项目总金额超过1000万元。与位于英国、爱尔兰、意大利、日本的多所高校、研究所和公司建立了长期、稳定的合作关系。目前承担的项目有：科技部政府间国际合作重点专项，项目编号：2016YFE**，大功率窄带宽中红外光纤激光器制备及性能联合研究，2017/01-2019/12，257万元，在研；国家自然科学基金面上项目，项目编号：**，基于中空多芯光纤的微球谐振腔光器件的特性研究，2016/01-2019/12，72万元，在研；黑龙江省自然科学基金重点项目，项目编号：ZD**，基于新型软玻璃材料基质的超窄线宽中红外波段光纤集成微腔谐振激光器件的研制，2016/07-2019/07，20万元，在研海外工作：先后申请、主持和参与科研项目共10项，项目合同金额合计约216万欧元。个人作为项目第一负责人（PI）的项目合同金额约89万欧元，其中欧美国际合作项目1项，欧盟项目1项，爱尔兰政府项目5项。

学术交流
国际交流与合作：在海外工作11年间，在国外光学科研领域拥有广泛的人脉基础，已经同下列国家的大学、研究所和公司建立了紧密的国际交流和合作：日本：电气通信大学、大阪大学、九州大学和冲绳科技大学英国：南安普敦大学、巴斯大学、伦敦城市大学、SPI lasers公司和Laser Components公司爱尔兰：都柏林理工学院、利默瑞克大学、都柏林大学和圣三一学院意大利：国家科学院微电子和微系统研究所、博洛尼亚大学和佛罗伦萨大学
招生信息
　　招生意向：具备自主学习能力，有扎实的光学、材料或激光相关专业的学习基础，有志于在光纤激光器、光纤传感技术、微纳光纤器件等热点研究领域进行探索和钻研。欢迎光学工程、光学、材料学、物理、电子工程、电子科学与技术等相关专业的本科生和研究生报考。 研究生当中的优秀代表可免面试推荐到国外知名研究机构进行联合培养研究。
本科生授课课程
研究生授课课程
光纤传感系统设计

实践性教学
教学研究课题
社会兼职
　　长期担任Laser & Photonics Reviews, Optica, Scientific Reports, ACS Photonics, Applied Physics Letters, Optics Express, Optics Letters等20多家国际知名学术期刊的审稿人。


专利成果


出版著作


发表论文
　　迄今已经在国际期刊和国际会议上发表文章180余篇，其中SCI检索国际期刊文章84篇。ISI Web of Science core collection上的H-index为18，文章累计被SCI检索引用1200余次，他引1000次；Google Scholar上的H-index为24，文章累计被Google Scholar检索引用1900余次。　
　　
[1]. Z. Gao, Y. Liu, J. Ren, Z. Fang, X. Lu, E. Lewis, G. Farrell, J. Yang and P. Wang*, “Selective doping of Ni²⁺ in highly transparent glass-ceramics containing nano-spinels ZnGa₂O₄ and Zn_1+xGa_2-2xGe_xO₄ for broadband near-infrared fiber amplifiers,” Scientific Reports, Vol. 7, Article no. 1783, 2017. (Corresponding author)
[2]. X. Wang, E. Lewis, P. Wang*, “Investigation of the Self-Imaging Position of a Singlemode-Multimode-Singlemode (SMS) Optical Fiber Structure,” Microwave and Optical Technology Letters, Vol. 59, No. 7, pp. 1645-1651, 2017. (Corresponding author)
[3]. Z. Fang, X. Xiao, X. Wang, Z. Ma, E. Lewis, G. Farrell, P. Wang*, J. Ren, H. Guo, J. Qiu, "Glass-ceramic optical fiber containing Ba₂TiSi₂O₈ nanocrystals for frequency conversion of lasers," Scientific Reports, Vol. 7, pp. 44456, 2017. (Corresponding author)
[4]. P. Wang, A. M. Hatta, H. Zhao, W. Yang, J. Ren, Y. Fan, G. Farrell, and G. Brambilla, "Passive photonic integrated ratiometric wavelength monitor with resolution better than 15 pm," Opt. Express, Vol. 25, No. 3, pp. 2939-2949, 2017.
[5]. K. Tian, Y. Xin, W. Yang, T, Geng, J. Ren, Y, Fan, G. Farrell, E. Lewis, and P. Wang*, "A curvature sensor based on twisted single-mode-multimode-single-mode hybrid optical fibre structure," Journal of Lightwave Technology, Vol. 35, No. 9, pp. 1725-1731, 2017. (Corresponding author)
[6]. L. She, P. Wang*, W. Sun, X. Wang, W. Yang, G. Brambilla, G. Farrell, "A Chalcogenide Multimode Interferometric Temperature Sensor Operating at a Wavelength of 2 μm," in IEEE Sensors Journal, Vol. 17, No. 6, pp. 1721-1726, 2017. (Corresponding author)
[7]. Y. Chu, J. Ren, J. Zhang, G. Peng, J. Yang, P. Wang* and Libo Yuan, “Ce³⁺/Yb³⁺/Er³⁺ triply doped bismuth borosilicate glass: a potential fiber material for broadband near-infrared fiber amplifiers,” Scientific Reports, Vol. 6, pp. 33865, 2016. (Corresponding author)
[8]. P. Wang, R. Madugani, H. Zhao, W. Yang, J. M. Ward, Y. Yang, G. Farrell, G. Brambilla and S. Nic Chormaic, “Packaged Optical Add-Drop Filter Based on an Optical Microfiber Coupler and a Microsphere,” IEEE Photonics Technology Letters, Vol. 28, No. 20, pp. 2277-2280, 2016.
[9]. B. Guo, Q. Lyu, Y. Yao and P. Wang*, “Direct generation of dip-type sidebands from WS 2 mode-locked fiber laser,” Optical Materials Express, Vol. 6, No. 8, pp. 2475-2486, 2016. (Corresponding author)
[10]. Y. Chu, J. Ren, J. Zhang, L. Liu, P. Wang, J. Yang, G. Peng, and L. Yuan, "Effects of melting temperature and composition on spectroscopic properties of Er³⁺-doped bismuth glasses," Opt. Mater. Express, Vol. 6, pp.279-287, 2016.
[11]. H. Zhao, G. Farrell, P. Wang and L. Yuan, “Investigation of particle harmonic oscillation using four-core fiber integrated twin-tweezers,” IEEE Photonics Technology Letters, Vol. 28, No. 4, pp. 461-464, 2015.
[12]. P. Wang, J. Ward, Y. Yang, X. Feng, G. Brambilla, G. Farrell and S. Nic Chormaic, "Lead silicate glass optical microbubble resonator," Applied Physics Letters, Vol. 106, No. 6, pp. 061101, 2015.
[13]. P. Wang, L. Bo, Y. Semenova, G. Farrell and G. Brambilla, “Optical microfiber based photonic components and their applications in label-free biosensing,” Biosensors, Vol. 5, pp. 471-499, 2015.
[14]. P. Wang, A. M. Hatta, H. Zhao, J. Zheng, G. Farrell and G. Brambilla, “A ratiometric wavelength measurement based on a Silicon-on-Insulator Directional coupler integrated device,” Sensors, Vol. 15, pp. 21280-21293, 2015.
[15]. L. Bo, P. Wang, Y. Semenova and G. Farrell, "Optical microfiber coupler based humidity sensor with a polyethylene oxide coating," Microwave and Optical Technology Letters, Vol. 57, No. 2, pp. 457-460, 2015.
[16]. P. Wang, T. Lee, M. Ding, Z. Lian, X. Feng, Y. Ma, L. Bo, Q. Wu, Y. Semenova, W. Loh, G. Farrell and G. Brambilla, "White Light Trapping Using Supercontinuum Generation Spectra in a Lead-Silicate Fibre Taper," IEEE/OSA Journal of Lightwave Technology, Vol. 32, No. 1, pp. 40-45, 2014.
[17]. P. Wang, M. Ding, L. Bo, C. Guan, Y. Semenova, W. Sun, L. Yuan, G. Brambilla and G. Farrell, "Photonic crystal fiber half taper probe based refractometer," Optics Letters, Vol. 39, No. 7, pp. 2076-2079, 2014.
[18]. P. Wang, M. Ding, G. S. Murugan, L. Bo, C. Guan, Y. Semenova, Q. Wu, G. Farrell and G. Brambilla, "Packaged high-Q microsphere resonator based add-drop filter," Optics Letters, Vol. 39, No. 17, pp. 5208-5211, 2014.
[19]. Q. Wu, J. Yuan, C. Yu, X. Sang, L. Sun, J. Li, T. Guo, B. Guan, H. Chan, K. Chiang, Y. Ma, P. Wang, Y. Semenova, and G. Farrell, "UV exposure on a single-mode fiber within a multimode interference structure," Opt. Lett., Vol. 39, No. 22, pp. 6521-6524, 2014.
[20]. Q. Wu, M. Ding, J. Yuan, H. Chan, Y. Ma, Y. Semenova, P. Wang, C. Yu and G. Farrell, "The use of a bend singlemode-multimode-singlemode (SMS) fibre structure for vibration sensing," Optics & Laser Technology, Vol. 63, pp. 29-33, 2014.
[21]. M. Ding, P. Wang, W. Wang, J. Wang and G. Brambilla, "FIB-milled Gold-coated Singlemode-Multimode-Singlemode Fiber Tip Refractometer," IEEE Photonics Technology Letters, Vol. 26, No. 3, pp. 239-241, 2014.
[22]. C. Guan, M. Ding, J. Shi, P. Hua, P. Wang, L. Yuan and G. Brambilla, "Experimental observation and analysis of all-fiber plasmonic double Airy beams," Optics Express, Vol. 22, No. 15, pp. 18365¨C18371, 2014.
[23]. C. Guan, M. Ding, J. Shi, P. Wang, P. Hua, L. Yuan and G. Brambilla, "Compact all-fiber plasmonic Airy-like beam generator," Optics Letters, Vol. 39, No. 5, pp. 1113-1116, 2014.
[24]. L. Bo, C. C. O’Mahony, Y. Semenova, N. Gilmartin, P. Wang and G. Farrell, "Microfiber coupler based label-free immunosensor," Optics Express, Vol. 22, No. 7, pp. 8150-8155, 2014. (Corresponding author)
[25]. P. Wang, M. Ding, L. Bo, C. Guan, Y. Semenova, Q. Wu, G. Farrell and G. Brambilla, "A fiber tip high temperature sensor based on multimode interference," Optics Letters, Vol. 38, No. 22, pp. 4617-4620, 2013.
[26]. P. Wang, L. Bo, C. Guan, Y. Semenova, Q. Wu, G. Brambilla and G. Farrell, "Low Temperature sensitivity periodically tapered photonic crystal fiber based refractometer," Optics Letters, Vol. 38, No. 19, pp. 3795-3798, 2013.
[27]. C. Grivas, C. Li, P. Andreakou, P. Wang, M. Ding, G. Brambilla, L. Manna, P. Lagoudakis, “Single-mode tunable laser emission in the single-exciton regime from colloidal nanocrystals,” Nature Communications, Vol. 4, pp. 2376, 2013.
[28]. Q. Wu, H. Chan, J. Yuan, Y. Ma, M. Yang, Y. Semenova, B. Yan, P. Wang, C. Yu, and G. Farrell, "Enhanced refractive index sensor using a combination of a long peroid fiber grating and a small core singlemode fiber structure," Measurement Science and Technology, Vol. 24, No. 9, pp. 094002, 2013.
[29]. C. Guan, J. Shi, M. Ding, P. Wang, P. Hua, L. Yuan and G. Brambilla, "In-line rainbow trapping based on plasmonic gratings in optical microfibers," Optics Express, Vol. 21, No. 14, pp. 16552-16560, 2013.
[30]. P. Wang, M. Ding, T. Lee, G. S. Murugan, L. Bo, Y. Semenova, Q. Wu, D. Hewak, G. Brambilla and G. Farrell, "Packaged chalcogenide microsphere resonator with high Q-factor," Applied Physics Letters, Vol. 102, pp. 131110, 2013.
[31]. P. Wang, C. C. O'Mahony, T. Lee, R. Ismaeel, T. Hawkins, Y. Semenova, L. Bo, Q. Wu, C. McDonagh, G. Farrell, J. Ballato and G. Brambilla, "Mid-infrared Raman sources using spontaneous Raman scattering in germanium core optical fibers," Applied Physics Letters, Vol. 102, No. 1, pp. 011111, 2013.
[32]. P. Wang, G. Brambilla, M. Ding, T. Lee, Lin Bo, Y. Semenova, Q. Wu, G. Farrell, "An enhanced refractometer based on periodically tapered small core singlemode fiber," IEEE Sensors Journal, Vol. 13, No. 1, pp. 180-185, 2013.
[33]. L. Bo, P. Wang, Y. Semenova, G. Farrell, "Highly-sensitive fiber refractometer based on an optical microfiber coupler," IEEE Photonics Technology Letters, Vol. 25, No. 3, pp. 228-230, 2013.
[34]. P. Wang, M. Ding, L. Bo, Y. Semenova, Q. Wu, G. Farrell, "A silica single-mode fibre-chalcogenide multimode fibre-silica singlemode fibre structure," Photonics Letters of Poland, Vol. 4, No. 4, pp. 143-145, 2012.
[35]. P. Wang, G. S. Murugan, T. Lee, G. Brambilla, M. Ding, Y. Semenova, Q. Wu, F. Koizumi and G. Farrell, “High-Q bismuth silicate nonlinear glass microsphere resonators,” IEEE Photonics Journal, Vol. 4, No. 3, pp. 1013-1020, June 2012.
[36]. P. Wang, G. S. Murugan, G. Brambilla, M. Ding, Y. Semenova, Q. Wu, G. Farrell, “Chalcogenide Microsphere Fabricated From Fiber Tapers Using Contact with a High Temperature Ceramic Surface,” IEEE Photonics Technology Letters, Vol. 24, No. 13, pp. 1103-1105, 2012.
[37]. P. Wang, M. Ding, G. Brambilla., Y. Semenova., Q. Wu., G. Farrell, “High temperature performance of an optical microfibre coupler and its potential use as a sensor,” Electronics Letters, Vol. 48, No. 5, pp. 283-284, 2012.
[38]. M. Ding, P. Wang, G. Brambilla, "A Fast-Response, High-Temperature Microfiber Coupler Tip thermometer," IEEE Photonics Technology Letters, Vol. 24, No. 14, pp. 1209-1211, 2012.
[39]. M. Ding, P. Wang, G. Brambilla, “A microfiber coupler tip thermometer,” Optics Express, Vol. 20, No. 5, pp.5402-5408, 2012.
[40]. Q. Wu, Y. Ma, J. Yuan, Y. Semenova, P. Wang, C. Yu, and G. Farrell, “Evanescent field coupling between two parallel close contact SMS fiber structures,” Optics Express, Vol. 20, No. 3, pp. 3098-3109, 2012.
[41]. Q. Wu, Y. Semenova, P. Wang, and G. Farrell, “Numerical investigation on a laser based localised joining with a glass frit intermediate layer,” Microsystem Technologies, Vol. 18, No. 1, pp. 87-92, 2012.
[42]. P. Wang, T. Lee, M. Ding, A. Dhar, T. Hawkins, P. Foy, Y. Semenova, Q. Wu, J. Sahu, G. Farrell, J. Ballato, and G. Brambilla, “Germanium microsphere high-Q resonator,” Optics Letters, Vol. 37, No. 4, pp. 728-730, 2012.
[43]. P. Wang, G. Brambilla, M. Ding, Y. Semenova, Q. Wu, G. Farrell, “The Use of a Fiber Comb Filter Fabricated By a CO₂ Laser Irradiation to Improve the Resolution of a Ratiometric Wavelength Measurement System,” Journal of Lightwave Technology, Vol. 30, No. 8, pp. 1143-1149, 2012.
[44]. Q. Wu, Y. Semenova, Y. Ma, P. Wang, T. Guo, L. Jin and G. Farrell, “Light coupling between a singlemode- multimode-singlemode (SMS) fiber structure and a long period fiber grating”, Journal of Lightwave Technology, Vol. 29, No. 24, pp. 3683-3688, 2011
[45]. Q. Wu, Y. Semenova, P. Wang, G. Farrell, “A comprehensive analysis verified by experiment of a refractometer based on an SMF28- Small-Core Singlemode fiber (SCSMF) -SMF28 fiber structure”, Journal of Optics, Vol. 13, No. 12, pp. 125401, 2011
[46]. M. Ding, P. Wang, T. Lee, G. Brambilla, “A microfiber cavity with minimal-volume confinement,” Applied Physics Letters, Vol. 99, pp. 051105, 2011.
[47]. P. Wang, G. Brambilla, M. Ding, Y. Semenova, Q. Wu, G. Farrell, “A high sensitivity, evanescent field refractometric sensor based on tapered multimode fiber interference,” Optics Letters, Vol. 36, No. 12, pp. 2233-2235, 2011.
[48]. P. Wang, G. S. Murugan, T. Lee, X. Feng, Y. Semenova, Q. Wu, W. Loh, G. Brambilla, J. S. Wilkinson and G. Farrell, “Lead silicate glass microsphere resonators with absorption-limited Q,” Applied Physics Letters, Vol. 98, pp. 181105, 2011.
[49]. P. Wang, G. Brambilla, Y. Semenova, Q. Wu, G. Farrell, “A simple ultrasensitive displacement sensor based on a high bend loss singlemode fibre and a ratiometric measurement system,” Journal of Optics, Vol. 13, pp. 075402, 2011.
[50]. P. Wang, G. Brambilla, M. Ding, Y. Semenova, Q. Wu, G. Farrell, “Investigation of singlemode-multimode-singlemode and singlemode-tapered multimode-singlemode fibre structures and their application for refractive index sensing,” Journal of the Optical Society of America B, Vol. 28, No. 5, pp. 1180-1186, 2011.
[51]. P. Wang, Y. Semenova, Q. Wu, G. Farrell, “A fiber-optic voltage sensor based on a macrobending structure,” Optics & Laser Technology, Vol. 43, No. 5, pp. 922-925, 2011.
[52]. P. Wang, Y. Semenova, J. Zheng, Q. Wu, A. M. Hatta, G. Farrell, “Numerical study of an ion-exchanged glass waveguide using both two-dimensional and three-dimensional models,” Optics & Laser Technology, Vol. 43, No. 4, pp. 882-888, 2011.
[53]. P. Wang, Y. Semenova, J. Zheng, Q. Wu, G. Farrell, “Proposal for a Simple Integrated Optical Ion Exchange Waveguide Polarizer with a Liquid Crystal Overlay,” Optics Communications, Vol. 284, pp. 979-984, 2011.
[54]. Q. Wu, Y. Semenova, P. Wang and G. Farrell, “Fibre heterostructure for simultaneous strain and temperature measurement,” Electronics Letters, Vol. 47, No. 12, pp. 713-714, 2011.
[55]. Q. Wu, Y. Semenova, B. Yan, Y. Ma, P. Wang, C. Yu and G. Farrell, “Fiber refractometer based on an FBG and SMS fiber structure,” Optics Letters, Vol. 36, No, 12, pp. 2197-2199, 2011.
[56]. Q. Wu, Y. Semenova, A. M. Hatta, P. Wang, G. Farrell, “Singlemode-Multimode-Singlemode fiber structures for simultaneous measurement of strain and temperature,” Microwave and Optical Technology Letters, Vol. 53, No. 9, pp. 2181-2185, 2011.
[57]. Q. Wu, Y. Semenova, J. Mathew, P. Wang and G. Farrell, “Humidity sensor based on a single-mode hetero-core fiber structure,” Optics Letters, Vol. 36, No, 10, pp. 1752-1754, 2011.
[58]. Q. Wu, Y. Semenova, P. Wang and G. Farrell, “High sensitivity SMS fiber structure based refractometer: analysis and experiment,” Optics Express, Vol. 19, No, 9, pp. 7937-7944, 2011.
[59]. Q. Wu, Y. Semenova, P. Wang, A. Hatta and G. Farrell, “Experimental demonstration of a simple displacement sensor based on a bent singlemode multimode singlemode fiber structure,” Measurement Science and Technology, Vol. 22, pp. 025203, 2011.
[60]. Q. Wu, A. Hatta, P. Wang, Y. Semenova and G. Farrell, “Use of a Bent Single SMS Fiber Structure for Simultaneous Measurement of Displacement and Temperature Sensing,” IEEE Photon. Tech. Lett., Vol. 23, No. 2, pp. 130-132, 2011.
[61]. J. Mathew, Y. Semenova, G. Rajan, P. Wang, G. Farrell, “Improving the sensitivity of a humidity sensor based on fiber bend coated with a hygroscopic coating,” Optics & Laser Technology, Vol. 43, No. 7, pp. 1301-1305, 2011.
[62]. P. Wang, Y. Semenova, Y. Li, Q. Wu, G. Farrell, “A macrobending singlemode fiber refractive index sensor for low refractive index liquids,” Photonics Letters of Poland, Vol. 2, No. 2, pp. 67-69, 2010.
[63]. P. Wang, Y. Semenova, Q. Wu, G. Farrell, “A bend loss based singlemode fiber micro-displacement sensor,” Microwave and Optical Technology Letters, Vol. 52, No. 10, pp. 2231-2235, 2010.
[64]. P. Wang, Y. Semenova, Q. Wu, J. Zheng, G. Farrell, “Temperature performance of a macrobending singlemode fiber based refractometer,” Applied Optics, Vol. 49, No. 10, pp. 1744-1749, 2010. (The paper has been selected and published on the Virtual Journal for Biomedical Optics-OSA, Vol. 5, Iss. 8, Jun. 8, 2010)
[65]. Q. Wu, Y. Semenova, G. Rajan, P. Wang and G. Farrell, “Study of the effect of source signal bandwidth on ratiometric wavelength measurement,” Applied Optics, Vol. 49, No. 29, pp. 5626-5631, 2010.
[66]. Q. Wu, Y. Semenova, A. M. Hatta, P. Wang and G. Farrell, “Bent SMS fiber structure for temperature measurement,” Electronics Letters, Vol. 46, No. 16, pp. 1129-1130, 2010.
[67]. Q. Wu, P. Wang, Y. Semenova and G. Farrell, “A study of the effect of the position of an edge filter within a ratiometric wavelength measurement system,” Measurement Science and Technology, Vol. 21, No. 9, pp. 094013, 2010.
[68]. Q. Wu, G. Rajan, P. Wang, Y. Semenova and G. Farrell, “Optimum design for maximum wavelength resolution for an edge filter-based ratiometric system,” Optics & Laser Technology, Vol. 42, pp. 1032-1037, 2010.
[69]. Q. Wu, Y. Semenova, A. Sun, P. Wang and G. Farrell, High resolution temperature insensitive interrogation technique for FBG sensors, Optics & Laser Technology, Vol. 42, pp. 653-656, 2010.
[70]. A. M. Hatta, Y. Semenova, G. Rajan, P. Wang, J. Zheng and G. Farrell, “Analysis of temperature dependence for a ratiometric wavelength measurement system using SMS fiber structure based edge filters,” Optics & Communications, Vol. 283, pp. 1291-1295, 2010.
[71]. P. Wang, Y. Semenova, Q. Wu, G. Farrell, Y. Ti, J. Zheng, “Macrobending single-mode fiber-based refractometer,” Applied Optics, Vol. 48, No. 31, pp. 6044-6049, 2009.
[72]. P. Wang, G. Farrell, Y. Semenova, “A generalized design process for fiber bend loss based edge filters for a wavelength measurement system,” Applied Optics, Vol. 48, No. 18, pp. 3055-3061, 2009.
[73]. P. Wang, G. Farrell, Y. Semenova, G. Rajan, “Investigation of Polarization Dependent Loss for a Macrobending Loss Sensitive Singlemode Fiber,” Microwave and Optical Technology Letters, Vol. 51, No. 6, pp. 1460-1464, 2009.
[74]. P. Wang, Y. Semenova, G. Rajan, T. Freir and G. Farrell, “The temperature dependence of polarization dependent loss for a macrobending singlemode fiber based edge filter,” IEEE Photonics Technology Letters, Vol. 21, No. 8, pp. 516-518, 2009.
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荣誉
2016年10月，入选日本学术振兴协会（JST）挑选的七位“亚洲青年创新科学家”之一。2014年3月，荣获爱尔兰皇家科学院优秀外派学者奖学金，获现金2000欧元奖励。2012年9月，基于我在玛丽居里学者合同期间的优异表现，获欧盟玛丽居里学会延长半年工作合同。合同总额约4万欧元。2010年10月，获玛丽居里学会颁发玛丽居里终身会员（Life-time membership）。2009年4月荣获“中国政府2008年度优秀海外自费留学生奖学金”，该奖项由中国国家留学基金委颁发，每年奖给300名最优秀的海外中国籍自费留学生，获5000美元现金奖励和获奖证书。
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