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易多 副教授

2020/06/15 17:42:52人浏览


    易多,男,博士,深圳大学物理与光电工程学院副教授。深圳市“孔雀计划”海外高层次人才,深圳市高层次人才后备级人才,南山区领航人才,国家科学基金委函评专家。博士毕业于法国贝尔福-蒙贝利亚大学(Université de Tchnologie de Belfort et Montbéliard)的LERMPS实验室,获得博士学位。后入职北京大学海洋声学与光纤传感实验室从事博士后研究工作。现就职于深圳大学物理与光电工程学院深圳市传感器技术重点实验室。长期从事光纤传感技术及跨学科领域的研究。主持基金包括中国博士后基金,国家自然科学基金青年基金等。近年来,已经在Optics Express,Optics Letters等光学领域国际权威SCI期刊及会议上发表论文近四十篇。申请及授权发明专利十二项。


附录:近3年发表部分论文

[1] F. Liu, D. Yi, Y. Chen, P. Xu, M. Zhang, X. Zhu, X. He, X. Zhou, and K. Long, "Common-mode noise self-suppressed 3-component fiber optic accelerometer based on low-reflectivity Bragg gratings," Opt. Lett. 46, 1596 (2021).

[2] Y. Chen, L. Fang, D. Yi, X. Li, and X. Hong, "Thermo-Optic Property Measurement Using Surface Plasmon Resonance-Based Fiber Optic Sensor," IEEE Sens. J. 20, 11357–11363 (2020).

[3] Y. Li, Y. Chen, D. Yi, Y. Du, W. Luo, X. Hong, X. Li, Y. Geng, and D. Luo, "A self-assembled fiber Mach-Zehnder interferometer based on liquid crystals," J MATER CHEM C 8, 11153-11159 (2020).

[4] Y. Li, L. Wang, Y. Chen, D. Yi, F. Teng, X. Hong, X. Li, Y. Geng, Y. Shi, and D. Luo, "High-performance fiber sensor via Mach-Zehnder interferometer based on immersing exposed-core microstructure fiber in oriented liquid crystals," OPT EXPRESS 28, 3576-3586 (2020).

[5] D. Yi, C. Yuzhi, G. Youfu, T. Fei, L. Yong, L. Xuejin, and H. Xueming, "Low crosstalk hybrid fiber optic sensor based on surface plasmon resonance and MMI," OPT LETT 1 (2020).

[6] D. Yi, Z. Huo, Y. Geng, X. Li, and X. Hong, "PDMS-coated no-core fiber interferometer with enhanced sensitivity for temperature monitoring applications," OPT FIBER TECHNOL 57 (2020).

[7]F. Liu, S. Xie, M. Zhang, B. Xie, Y. Pan, X. He, D. Yi, L. Gu, Y. Yang, Z. Chen, H. Lu, and X. Zhou, "Downhole Microseismic Monitoring Using Time-Division Multiplexed Fiber-Optic Accelerometer Array," IEEE Access 8, 120104–120113 (2020).

[8]F. Teng, D. Yi, X. Hong, and X. Li, "Distributed fiber optics disturbance sensor using a dual-Sagnac interferometer," OPT LETT 44, 5101-5103 (2019).

[9]D. Yi, F. Liu, M. Zhang, and Q. Tao, "High-accuracy transient response fiber optic seismic accelerometer using a shock-absorbing ring as a mechanical antiresonator," OPT LETT 44, 183-186 (2019).

[10]L. Wang, Y. Xu, Y. Geng, J. Wang, Y. Du, D. Yi, X. Hong, and X. Li, "High-sensitivity fiber salinity sensor based on an exposed-core microstructured fiber interferometer," J PHYS D APPL PHYS 52, 495402 (2019).

[11]F. Liu, S. Xie, L. Gu, X. He, D. Yi, Z. Chen, M. Zhang, and Q. Tao, "Common-Mode Noise Suppression Technique in Interferometric Fiber-Optic Sensors," J. Light. Technol. 37, 5619–5627 (2019).

[12]D. Yi, F. Liu, X. He, and M. Zhang, "Experimental study on transient response of the fiber optic seismic accelerometer," OPT FIBER TECHNOL 45, 58-63 (2018).

[13]D. Yi, X. He, F. Liu, L. Gu, M. Zhang, X. Qiu, and H. Ye, "Self-suppression of common-mode noises of the different fiber optic interferometric accelerometers," OPT EXPRESS 26, 15384-15397 (2018).

[14]F. Liu, L. Gu, S. Xie, X. He, D. Yi, M. Zhang, and Q. Tao, "Acousto-Optic Modulation Induced Noises on Heterodyne-Interrogated Interferometric Fiber-Optic Sensors," J. Light. Technol. 36, 3465–3471 (2018).

[15]X. He, M. Zhang, S. Xie, F. Liu, L. Gu, and D. Yi, "Self-Referenced Accelerometer Array Multiplexed on a Single Fiber Using a Dual-Pulse Heterodyne Phase-Sensitive OTDR," J. Light. Technol. 36, 2973–2979 (2018).

[16]X. He, Y. Pan, H. You, Z. Lu, L. Gu, F. Liu, D. Yi, and M. Zhang, "Fibre optic seismic sensor for down-well monitoring in the oil industry," Measurement 123, 145–149 (2018).


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