基本信息
于飞 男 博导 中国科学院上海光学精密机械研究所
电子邮件: yufei@siom.ac.cn
通信地址: 上海市嘉定区汇旺东路899号
邮政编码: 201800
电子邮件: yufei@siom.ac.cn
通信地址: 上海市嘉定区汇旺东路899号
邮政编码: 201800
研究领域
微结构光纤设计、制备与测试;基于微结构光纤的光纤激光器、气体非线性光学研究
招生信息
物理学、光电子与光学背景研究生
招生专业
080300-光学工程
招生方向
微结构光纤及其应用非线性光学光纤激光器
教育背景
2010-10--2014-02 英国巴斯大学 博士2008-09--2010-07 北京理工大学 硕士2004-09--2008-06 北京理工大学 本科
工作经历
工作简历
2020-01~现在, 中国科学院上海光学精密机械研究所, 研究员2018-03~2019-12,中国科学院上海光学精密机械研究所, 副研究员2014-02~2018-03,英国巴斯大学, 博士后研究员
专利与奖励
专利成果
[1] 于春雷, 程跃, 阳求柏, 朱一鸣, 于飞, 胡丽丽. 一种全固态反谐振光纤及其制备方法. CN: CN118198838A, 2024-06-14.[2] 于飞, 任晓琴, 周宁, 栾书凡, 赵笑冬, 谢佳奇, 于春雷, 胡丽丽. 一种基于金纳米棒-微光纤模式强耦合结构的湿度传感器. CN: CN118169078A, 2024-06-11.[3] 于飞, 徐炳生, 沈赫男. 一种空气包层多芯光纤传像束及其制备方法. CN: CN117970560A, 2024-05-03.[4] 于春雷, 尚浩睿, 于飞, 吴达坤, 朱昕玥. 发光物体的空间光谱全自动测量装置及方法. CN: CN116972973A, 2023-10-31.[5] 于飞, 赵喜龙, 吴达坤, 朱昕玥. 基于有源多芯光纤的高重频光纤激光器. CN: CN116417884A, 2023-07-11.[6] 于飞, 郑金虎, 吴达坤, 栾书凡. 基于复用反谐振空芯光纤传输探测模块. CN: CN115436337A, 2022-12-06.[7] 于飞, 郑金虎, 吴达坤, 栾书凡. 基于复用反谐振空芯光纤传输探测模块. CN: CN115436337B, 2024-04-12.[8] 于飞, 伍成, 冯素雅, 于春雷, 胡丽丽, 吴达坤. 少模保偏光纤拍长测量方法. CN: CN115371968A, 2022-11-22.[9] 于飞, 孙亚丽, 朱昕玥, 梁乐本, 郑金虎. 实时监测和净化空芯光纤中气态OH的系统和方法. CN: CN115372357A, 2022-11-22.[10] 于飞, 孙亚丽, 朱昕玥, 梁乐本, 郑金虎. 实时监测和净化空芯光纤中气态OH的系统和方法. CN: CN115372357B, 2024-04-12.[11] 贺冬钰, 廖梅松, 房永征, 胡丽丽, 王欣, 孙焰, 于飞, 薛天锋. 红光组分增强的YAG复合荧光玻璃的制备方法. CN: CN115140938A, 2022-10-04.[12] 王亚洲, 于飞. 面向色散可调的多层变径实芯光子晶体光纤及其制备方法. CN: CN115677207A, 2023-02-03.[13] 林鑫, 于飞, 孙亚丽, 李仁杰, 方思晗, 李飞, 余西龙. 一种基于反谐振空芯光纤的自标定TDLAS方法及系统. CN: CN114839160A, 2022-08-02.[14] 于飞, 沈超超. 基模为方形场的单模反谐振空芯光纤. CN: CN114815042A, 2022-07-29.[15] 于飞, 朱昕玥. 大功率激光空芯光纤气体填充耦合端子. CN: CN114865430A, 2022-08-05.[16] 于飞, 管景昭, 韩颖. 一种非破坏式微结构光纤侧面散射损耗测量装置和方法. CN: CN114878140B, 2023-01-20.[17] 于飞, 管景昭, 韩颖. 一种非破坏式微结构光纤侧面散射损耗测量装置和方法. CN: CN114878140A, 2022-08-09.[18] 于飞, 梁乐本, 朱昕玥, 孙亚丽, 郑金虎. 一种空芯光纤封装及其制作方法. CN: CN114910994A, 2022-08-16.[19] 于飞, 甘琳巧, 于春雷, 胡丽丽. 一种长锥区的光纤拉锥装置. CN: CN114442231B, 2023-09-01.[20] 于飞, 甘琳巧, 于春雷, 胡丽丽. 一种长锥区的光纤拉锥装置. CN: CN114442231A, 2022-05-06.[21] 于飞, 甘琳巧, 于春雷, 胡丽丽. 一种长锥区的光纤拉锥装置. CN: CN114442231A, 2022-05-06.[22] 于飞, 瞿飞, 胡丽丽, 徐炳生. 一种有序排列的高NA多芯成像光纤及其制备方法. CN: CN114200575A, 2022-03-18.[23] 冯丽爽, 吴达坤, 刘惠兰, 于飞, 李谊军, 吴润龙, 王聪昊, 吴丹磊. 光纤和内窥镜. CN: CN113940613A, 2022-01-18.[24] 陈亮, 沈亚婷, 廖梅松, 李夏, 胡丽丽, 于飞, 关佩雯, 毕婉君, 王龙飞, 王天行. 多芯保偏光子晶体光纤. CN: CN114185126A, 2022-03-15.[25] 廖梅松, 陈亮, 毕婉君, 李夏, 关佩雯, 胡丽丽, 于飞, 王天行, 王龙飞. 平坦的超连续谱光源. CN: CN112260046A, 2021-01-22.[26] 关珮雯, 李夏, 廖梅松, 毕婉君. 一种光纤准直器. CN: CN112255815A, 2021-01-22.[27] 关珮雯, 李夏, 廖梅松. 一种光纤准直器. CN: CN112255815B, 2021-07-06.[28] 关珮雯, 李夏, 廖梅松, 毕婉君, 王天行, 于飞, 王龙飞. 一种光纤准直器. CN: CN112255815B, 2021-07-06.[29] 廖梅松, 蔡宏波, 于飞, 吴达坤. 9芯结构的细径保偏光子带隙光纤及制备方法. CN: CN110927861B, 2021-05-04.[30] 廖梅松, 王天行, 毕婉君, 李夏, 关珮雯, 刘垠垚, 于飞, 王龙飞. 基于高功率多模激光器和超多芯高非线性光纤的超连续谱光源. CN: CN112242640B, 2022-01-28.[31] 廖梅松, 王天行, 毕婉君, 李夏, 关珮雯, 刘垠垚, 于飞, 王龙飞. 基于高功率多模激光器和超多芯高非线性光纤的超连续谱光源. CN: CN112242640A, 2021-01-19.[32] 王天行, 毕婉君, 李夏, 关珮雯, 刘垠垚, 廖梅松, 于飞, 王龙飞, 胡丽丽. 全光纤化大能量超连续谱激光器. CN: CN112152056A, 2020-12-29.
出版信息
发表论文
[1] Renjie Li, , 于飞, Jing Li, Dong He, Fei Li, Xin Lin. A nonparametric point-by-point method to measure time-dependent frequency in wavelength modulation spectroscopy. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy[J]. 2025, 第 2 作者null(null): [2] 郑金虎, 徐炳生, 沈赫男, 于飞, 陈建. 应用于相干成像的一种螺旋多芯光纤设计. 光子学报[J]. 2024, 第 4 作者 通讯作者 53(1): 212-221, https://doi.org/10.3788/gzxb20245301.0106001.[3] Zhao, Meng, Yu, Fei, Wu, Dakun, Zhu, Xinyue, Chen, Si, Wang, Meng, Liu, Minzhe, Zhao, Kun, Zhai, Ruizhan, Jia, Zhongqing, Knight, Jonathan. Delivery of nanosecond laser pulses by multi-mode anti-resonant hollow core fiber at 1 μm wavelength. OPTICS EXPRESS[J]. 2024, 第 2 作者 通讯作者 32(10): 17229-17238, http://dx.doi.org/10.1364/OE.523786.[4] Luan, Shufan, Chen, Si, Zhu, Xinyue, Wu, Dakun, Yu, Fei, Hu, Junjiang, Yu, Chunlei, Hu, Lili. In-situ background-free Raman probe using double-cladding anti-resonant hollow-core fibers. BIOMEDICAL OPTICS EXPRESS[J]. 2024, 第 5 作者 通讯作者 15(3): http://dx.doi.org/10.1364/BOE.517625.[5] He'nan Shen, Xilong Zhao, 于飞, Yazhou Wang, Yafei Wang, Yan Sun, Shikai Wang, Yinggang Chen, 贾中青, 翟瑞占, chunlei yu, lili hu. Mode-locked fiber lasers at 1064 and 910 nm wavelengths using Nd3+-doped silica fiber. chinese optics letters[J]. 2024, 第 3 作者null(null): [6] Mingjie Yao, Jingmin Liu, Xu Chen, Xinyue Zhu, Zhuo Chen, Dakun Wu, 于飞, Xia Yu. Efficient high-power 1.9 µm picosecond Raman laser in H2-filled hollow-core fiber without generation of rotational lines. Optics & Laser Technology 181[J]. 2024, 第 7 作者null(null): [7] Pan, Jinyu, Huang, Zhiyuan, Chen, Yifei, Luo, Zhuozhao, Yu, Fei, Wu, Dakun, Chen, Tiandao, Liu, Donghan, Yu, Yue, He, Wenbin, Jiang, Xin, Pang, Meng, Leng, Yuxin, Li, Ruxin. Broadband Dispersive-Wave Emission Coupled with Two-Stage Soliton Self-Compression in Gas-Filled Anti-Resonant Hollow-Core Fibers. LASER & PHOTONICS REVIEWS. 2024, 第 5 作者http://dx.doi.org/10.1002/lpor.202400531.[8] chinese optics letters. 2024, 第 3 作者 通讯作者 [9] chinese optics letters. 2024, 第 3 作者 通讯作者 [10] Wang, Lidong, Liao, Meisong, Yu, Fei, Li, Weichang, Xu, Jiacheng, Hu, Lili, Gao, Weiqing. Thermal Sensitivity of Birefringence in Polarization-Maintaining Hollow-Core Photonic Bandgap Fibers. PHOTONICS[J]. 2023, 第 3 作者10(2): http://dx.doi.org/10.3390/photonics10020103.[11] Liang, Leben, Guan, Jingzhao, Zhu, Xinyue, Wang, Yazhou, Wu, Dakun, Yu, Fei, Han, Ying. Delivery of Nearly Diffraction-Limited Picosecond Laser Pulses in the Air-Filled Anti-Resonant Hollow-Core Fiber at 1 mu m Wavelength. PHOTONICS[J]. 2023, 第 6 作者 通讯作者 10(4): http://dx.doi.org/10.3390/photonics10040416.[12] Wu, Dakun, Yu, Fei, Wu, Cheng, Zhao, Meng, Zheng, Jinhu, Hu, Lili, Knights, Jonathan. Low-loss multi-mode anti-resonant hollow-core fibers. OPTICS EXPRESS[J]. 2023, 第 2 作者 通讯作者 31(13): 21870-21880, http://dx.doi.org/10.1364/OE.492787.[13] Zhao, Chunzhu, Chen, Shiyuan, Zhang, Lifeng, Zhang, Dong, Wu, Runlong, Hu, Yanhui, Zeng, Fengqingyang, Li, Yijun, Wu, Dakun, Yu, Fei, Zhang, Yunfeng, Zhang, Jue, Chen, Liangyi, Wang, Aimin, Cheng, Heping. Miniature three-photon microscopy maximized for scattered fluorescence collection. NATURE METHODS[J]. 2023, 第 10 作者20(4): http://dx.doi.org/10.1038/s41592-023-01777-3.[14] Shi, Zhaojiang, Yang, Shichao, Yu, Fei, Yu, Xia. Investigation of the laser-sustained plasma of a Xenon lamp driven by an annular beam. OPTICS EXPRESS[J]. 2023, 第 3 作者31(4): 6132-6142, http://dx.doi.org/10.1364/OE.480954.[15] Leben Liang, Jingzhao Guan, Xinyue Zhu, Yazhou Wang, Dakun Wu, Fei Yu, Ying Han. Delivery of Nearly Diffraction-Limited Picosecond Laser Pulses in the Air-Filled Anti-Resonant Hollow-Core Fiber at 1 μm Wavelength. PHOTONICS[J]. 2023, 第 6 作者10(416): https://doaj.org/article/63b8bb1b3f9441ef8d8897c3462fcbfd.[16] Wu, Cheng, Yu, Fei, Feng, Suya, Yu, Chunlei, Xu, Lixin, Zhai, Ruizhan, Jia, Zhongqing, Hu, Lili. Application of Crossed Polarizer Method in the Measurement of Differential Group Delay of Optical Fibers. PHOTONICS[J]. 2023, 第 2 作者 通讯作者 10(5): http://dx.doi.org/10.3390/photonics10050518.[17] Wang, Lidong, Liao, Meisong, Yu, Fei, Chen, Liang, Wang, Yazhou, Wu, Dakun, Wang, Tianxing, Hu, Lili, Gao, Weiqing. The Structural Defects and Optical Performance of Polarization-Maintaining Hollow-Core Photonic Bandgap fiber. IEEE PHOTONICS JOURNAL[J]. 2023, 第 3 作者15(3): http://dx.doi.org/10.1109/JPHOT.2023.3278930.[18] Jaworski, Piotr, Wu, Dakun, Yu, Fei, Krzempek, Karol. Direct performance comparison of antiresonant and Kagome hollow-core fibers in mid-IR wavelength modulation spectroscopy of ethane. OPTICS EXPRESS[J]. 2023, 第 3 作者31(15): 24810-24820, http://dx.doi.org/10.1364/OE.493177.[19] Ge, Mengying, Chen, Liang, Liao, Meisong, Yu, Fei, Wu, Dakun, Wang, Tianxing, Gao, Weiqing, Hu, Lili. Supercontinuum Shaping via Hollow Core Anti-Resonant Fiber. PHOTONICS[J]. 2023, 第 4 作者10(5): http://dx.doi.org/10.3390/photonics10050528.[20] 孙亚丽, 朱昕玥, 吴达坤, 伍成, 于飞, 李仁杰, 林鑫, 赵文凯. 基于反谐振空芯光纤的中红外TDLAS系统设计及应用实验研究. 光学学报[J]. 2023, 第 5 作者43(13): 71-80, http://lib.cqvip.com/Qikan/Article/Detail?id=7110372200.[21] Gan, Linqiao, Yu, Fei, Wang, Yazhou, Wang, Ning, Zhu, Xinyue, Hu, Lili, Yu, Chunlei. Dispersion-Oriented Inverse Design of Photonic-Crystal Fiber for Four-Wave Mixing Application. PHOTONICS[J]. 2023, 第 2 作者 通讯作者 10(3): http://dx.doi.org/10.3390/photonics10030294.[22] Qu, Fei, Xu, Bingsheng, Yu, Fei, Li, Fei, Lin, Xin. Bend-resistant high-resolution imaging optical fiber. OPTICS AND LASER TECHNOLOGY[J]. 2023, 第 3 作者 通讯作者 157: http://dx.doi.org/10.1016/j.optlastec.2022.108650.[23] Sabbah, Mohammed, Belli, Federico, Brahms, Christian, Yu, Fei, Knight, Jonathan, Travers, John C. Generation and characterization of frequency tunable sub-15-fs pulses in a gas-filled hollow-core fiber pumped by a Yb:KGW laser. OPTICS LETTERS[J]. 2023, 第 4 作者48(9): 2277-2280, http://dx.doi.org/10.1364/OL.484040.[24] Zhu, Xinyue, Yu, Fei, Wu, Dakun, Chen, Shufen, Jiang, Yi, Hu, Lili. Laser-induced damage of an anti-resonant hollow-core fiber for high-power laser delivery at 1 mu m. OPTICS LETTERS[J]. 2022, 第 2 作者 通讯作者 47(14): 3548-3551, [25] Zhu, Xinyue, Yu, Fei, Wu, Dakun, Feng, Yan, Chen, Shufen, Jiang, Yi, Hu, Lili. Low-threshold continuous operation of fiber gas Raman laser based on large-core anti-resonant hollow-core fiber. CHINESE OPTICS LETTERS[J]. 2022, 第 2 作者 通讯作者 20(7): 18-23, http://dx.doi.org/10.3788/COL202220.071401.[26] Gu, Yitong, Wang, Ning, Shang, Haorui, Yu, Fei, Hu, Lili. Investigations on Grating-Enhanced Waveguides for Wide-Angle Light Couplings. NANOMATERIALS[J]. 2022, 第 4 作者12(22): http://dx.doi.org/10.3390/nano12223991.[27] Bojes, Piotr, Pokryszka, Piotr, Jaworski, Piotr, Yu, Fei, Wu, Dakun, Krzempek, Karol. Quartz-Enhanced Photothermal Spectroscopy-Based Methane Detection in an Anti-Resonant Hollow-Core Fiber. SENSORS[J]. 2022, 第 4 作者22(15): http://dx.doi.org/10.3390/s22155504.[28] Wang, Conghao, Liu, Huilan, Cui, Haodong, Ma, Jianrui, Li, Yijun, Tian, Jingquan, Jin, Chaoyong, Chen, Yanchuan, Gao, Yuqian, Fu, Qiang, Hu, Yanhui, Wu, Dakun, Yu, Fei, Wu, Runlong, Wang, Aimin, Feng, Lishuang. Two-photon endomicroscopy with microsphere-spliced double-cladding antiresonant fiber for resolution enhancement. OPTICS EXPRESS[J]. 2022, 第 13 作者30(15): 26090-26101, http://dx.doi.org/10.1364/OE.461325.[29] Bojes, Piotr, Jaworski, Piotr, Krzempek, Karol, Malecha, Ziemowit, Yu, Fei, Wu, Dakun, Koziol, Pawel, Dudzik, Grzegorz, Liao, Meisong, Abramski, Krzysztof. Experimental and numerical analysis of gas flow in nodeless antiresonant hollow-core fibers for optimization of laser gas spectroscopy sensors. OPTICS AND LASER TECHNOLOGY[J]. 2022, 第 5 作者152: http://dx.doi.org/10.1016/j.optlastec.2022.108157.[30] 沈超超, 于飞, 于春雷, 胡丽丽. 高功率激光运转条件下大模场掺镱石英光纤模式特性的仿真研究. 光学学报[J]. 2022, 第 2 作者42(10): 107-114, http://lib.cqvip.com/Qikan/Article/Detail?id=7107420058.[31] Jaworski, Piotr, Krzempek, Karol, Koziol, Pawel, Wu, Dakun, Yu, Fei, Bojes, Piotr, Dudzik, Grzegorz, Liao, Meisong, Knight, Jonathan, Abramski, Krzysztof. Sub parts-per-billion detection of ethane in a 30-meters long mid-IR Antiresonant Hollow-Core Fiber. OPTICS AND LASER TECHNOLOGY[J]. 2022, 第 5 作者147: http://dx.doi.org/10.1016/j.optlastec.2021.107638.[32] Jaworski, Piotr, Krzempek, Karol, Bojes, Piotr, Wu, Dakun, Yu, Fei. Mid-IR antiresonant hollow-core fiber based chirped laser dispersion spectroscopy of ethane with parts per trillion sensitivity. OPTICS AND LASER TECHNOLOGY[J]. 2022, 第 5 作者156: http://dx.doi.org/10.1016/j.optlastec.2022.108539.[33] Ma, Juping, Jiao, Yan, Shao, Chongyun, Sun, Yan, Jiang, Yiguang, Yu, Fei, Hu, Lili. fluorophosphate, and fluoride glasses. OPTICAL MATERIALS[J]. 2022, 第 6 作者127: http://dx.doi.org/10.1016/j.optmat.2022.112329.[34] Challener, William A, Kasten, Ansas M, Yu, Fei, Puc, Gabriel, Mangan, Brian J. Dynamics of Trace Methane Diffusion/Flow Into Hollow Core Fiber Using Laser Absorption Spectroscopy. IEEE SENSORS JOURNAL[J]. 2021, 第 3 作者21(5): 6287-6292, http://dx.doi.org/10.1109/JSEN.2020.3042345.[35] 徐嘉程, 于飞, 徐炳生, 于春雷, 胡丽丽. 牵引张力和热处理对熊猫型保偏光纤双折射影响研究. 光子学报[J]. 2021, 第 2 作者50(11): 80-90, https://doi.org/10.3788/gzxb20215011.1106002.[36] He, Dongyu, Fang, Yongzheng, Liao, Meisong, Zhao, Guoying, Sun, Yan, Yu, Fei, Hu, Lili, Wang, Xin, Hou, Jingshan, Xue, Tianfeng, Liu, Yufeng. Luminescence properties and energy transfer behavior of Dy3+/Tm 3+co-doped phosphate glasses with high moisture-resistance and thermal stability for W-LEDs. JOURNAL OF LUMINESCENCE[J]. 2021, 第 6 作者236: http://dx.doi.org/10.1016/j.jlumin.2021.118087.[37] Wang, Yazhou, Yu, Fei, Hu, Lili. Inverse Design of Equivalent-Graded-Index Photonic-Crystal Fiber Based on Empirical Dispersion Formula. JOURNAL OF LIGHTWAVE TECHNOLOGY[J]. 2021, 第 2 作者 通讯作者 39(17): 5598-5603, [38] Zhu, Xinyue, Wu, Dakun, Wang, Yazhou, Yu, Fei, Li, Qiurui, Qi, Yunfeng, Knight, Jonathan, Chen, Shufen, Hu, Lili. Delivery of CW laser power up to 300 watts at 1080 nm by an uncooled low-loss anti-resonant hollow-core fiber. OPTICS EXPRESS[J]. 2021, 第 4 作者 通讯作者 29(2): 1492-1501, https://www.webofscience.com/wos/woscc/full-record/WOS:000609227300039.[39] Fu, Jianhua, Chen, Yifei, Huang, Zhiyuan, Yu, Fei, Wu, Dakun, Pan, Jinyu, Zhang, Cheng, Wang, Ding, Pang, Meng, Leng, Yuxin. Photoionization-Induced Broadband Dispersive Wave Generated in an Ar-Filled Hollow-Core Photonic Crystal Fiber. CRYSTALS[J]. 2021, 第 4 作者11(2): https://doaj.org/article/7d347285ff4e4b74a45682c31519acad.[40] Ehrlich, Katjana, Choudhary, Tushar R, Ucuncu, Muhammed, MegiaFernandez, Alicia, Harrington, Kerrianne, Wood, Harry A C, Yu, Fei, Choudhury, Debaditya, Dhaliwal, Key, Bradley, Mark, Tanner, Michael G. Time-Resolved Spectroscopy of Fluorescence Quenching in Optical Fibre-Based pH Sensors. SENSORS[J]. 2020, 第 7 作者20(21): https://doaj.org/article/a929142be96f4c409eac5ff02a437c82.[41] Wu, Dakun, Yu, Fei, Liao, Meisong. 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