朱程亮,男,1986年2月出生,博士,副教授,博士生导师。
联系方式
联系电话:18302478766
电子邮件:zhuchengliang@neuq.edu.cn
研究方向
先进光纤器件与传感研究室,面向智能光传感系统与超大容量光通信系统,围绕光纤器件,开展以下方面研究。
1. 新型光子器件最优化设计与先进制备
2. 光纤传感理论与智能检测技术
3. 光子角动量(轨道/自旋)模式生成与应用
4. 特种材料与器件全自动化测试
5. 微波光子学及其传感应用
教育背景
2006.04-2010.03 日本国立静冈大学 系统工学(光电系统) 学士(工学)
2010.04-2012.03 日本国立静冈大学 系统工学(光电系统) 硕士(工学)
2016.10-2019.09 日本国立静冈大学 光电子及纳米结构科学 博士(工学)
工作履历
2012.04-2016.05 Makita株式会社 日本总部 研发工程师(终身制职员)
2016.10-2019.09 日本国立静冈大学 创造科学技术大学院 学术研究员(兼职)
2016.10-2019.09 日本国立静冈大学 工学部 研究助手(兼职)
2019.12-至今 东北大学 秦皇岛分校 副教授
学术兼职
中国光学学会会员
The Institute of Electrical and Electronics Engineers (IEEE) 会员。
Institute of Electronics, Information and Communication Engineers (IEICE)会员。
MDPI SENSORS、Frontiers in Sensors期刊编辑
Optics Letters,Optics Express,IEEE/OPTICA Journal of Lightwave Technology,IEEE Photonics Technology Letters,Infrared Physics and Technology,Optics Communications,Optical fiber technology等SCI期刊审稿人。
科研项目
1. 河北省自然科学基金,面上项目,2024-2026,主持
2. 国家自然科学基金,联合基金项目,2023-2026,参与
3. 教育部中央高校基本业务费,培育项目,2022-2023,主持
4. 日本文部科学省基盤研究项目B,2022-2024,参与
5. 国家自然科学基金,青年项目,2021-2023,主持
6. 河北省教育厅高等学校科学研究,青年拔尖人才计划项目,2021-2023,主持
7. 河北省自然科学基金,绿色通道项目,2020-2022,主持
8. 日本KDDI财团研究助成项目,2019-2020,参与
9. 日本电气通信普及财团研究助成项目,2018-2019,参与
10. 日本板硝子材料工学助成会研究助成项目,2018-2019,参与
11. 日本卡西欧科学振兴财团研究助成项目,2016-2017,参与
12. 日本电信电话株式会社(NTT)合作研究项目,2010-2012,参与
13. 日本文部科学省基盤研究项目C,2008-2010,参与
奖励与荣誉
2019 年度日本电子情报通信学会博士研究奖励赏,日本电子情报通信学会东海支部;(日本东海地区唯一获奖博士)
2019年度Dean's award for graduate school of science and technology, Shizuoka University. (唯一获奖博士)
2012&2015年度 Makita集团全球最佳员工奖(科室全体)
学术成果
【论文、专著与专利等】
研究成果在主流SCI期刊,如Optics Letters,IEEE/OPTICA Journal of Lightwave Technology, Optics Express, IEEE Transactions on Instrumentation and Measurement,Optics and Laser Technology, IEEE Journal of Quantum Electronic, IEEE Photonics Technology Letters, IEEE Photonics Journal等以及IEEE,OPTICA,SPIE,IEICE等学会举办的国际会议发表论文60余篇,申请日本及中国专利6项,在SPIE/COS Photonics Asia、SPIE IACOP、SPIE OCOIP、全国光子学学术会议等作特邀报告6次。
【代表性学术论文】
*代表性SCI期刊论文*
[1] Zhu Chengliang*, et al. Ultralow-duty-cycle amplitude-sampled LPFG using deep tapering and its application to cross-sensitivity-free multiparameter sensor, IEEE/OPTICA Journal of Lightwave Technology, 2025, 43(5), 2321-2328.
[2] Zhu Chengliang*, et al. Ultrahigh-channel-count OAM mode conversion utilizing a hybrid few-mode fiber configuration, Optics Letters, 2024, 49(16), 4626-4629.
[3] Zhu Chengliang*, et al. Generation of optical vortex beams with bandwidth exceeding 550 nm using a helical fiber needle exhibiting strong mode coupling, Optics Letters, 2024, 49(10), 2561-2564. 【Editor’s Pick】
[4] Zhu Chengliang*, et al. Deeply-tapered ultrashort long-period fiber grating and its application to ultrasensitive transverse-load sensor. IEEE/OPTICA Journal of Lightwave Technology, 2023, 41(18): 6108-6115.
[5] Zhu Chengliang*, et al. Ultra-wideband OAM mode generator based on a helical grating written in a graded-index few-mode fiber. IEEE/OPTICA Journal of Lightwave Technology, 2023, 41(5):1533-1538.
[6] Zhu Chengliang*, et al. Miniature temperature-independent curvature sensor based on a phase-shifted long-period fiber grating using deep tapering. IEEE Sensors Journal, 2023, 30(19): 14174-14181.
[7] Zhu Chengliang*, et al. Cross-sensitivity-free highly sensitive torsion and strain sensor based on concatenated DTP-customizable helical fiber gratings. IEEE Sensors Journal, 2023, 23(22): 27423-27430.
[8] Zhu Chengliang, et al. On-demand flat-top wideband OAM mode converter based on a cladding-etched helical fiber grating. Optics express, 2023, 31(26): 43477-43489.
[9] Zhu Chengliang, et al. Ultra-broad edge filter based on a periodically twisted graded-index fiber and its application to power-interrogated temperature sensor. Optics express, 2022, 30(19): 34776-34786.
[10] Zhu Chengliang*, et al. Reflective-type multiparameter sensor based on a paired helical fiber gratings and a trapezoid-Like micro cavity. IEEE Transactions on Instrumentation and Measurement, 2022, 70, 7001607.
[11] Zhu Chengliang, et al. Optimal design and fabrication of multichannel helical long-period fiber gratings based on phase-only sampling method. Optics express, 2019, 27(3): 2281-2291.
[12] Zhu Chengliang, et al. Multichannel long-period fiber grating realized by using the helical sampling approach. IEEE/OPTICA Journal of Lightwave Technology, 2019, 37(9): 2008-2013.
[13] Zhu Chengliang, et al. Phase-Inserted Fiber Gratings and Their Applications to Optical Filtering, Optical Signal Processing, and Optical Sensing: Review. Photonics, 2022, 9(4): 271. 【EDITOR'S CHOICE ARTICLES】
[13] Zhu Chengliang*, et al. Simultaneous measurement of directional torsion and temperature by using a DC-sampled helical long-period fiber grating. Optics and Laser Technology, 2021, 142: 1-7.
[15] Zhu Chengliang, et al. DC-Sampled Helical Fiber Grating and its Application to Multi-Channel OAM Generator. IEEE Photonics Technology Letters, 2019, 31(17): 1445-1448.
[16] Zhu Chengliang*, et al. Ultra-Broadband OAM Mode Generator Based on a Phase-Modulated Helical Grating Working at a High Radial-Order of Cladding Mode. IEEE Journal of Quantum Electronics, 2021, 57(4): 6800307.
[17] Zhu Chengliang, et al. All-fiber circular polarization filter realized by using helical long-period fiber gratings. IEEE Photonics Technology Letters, 2018, 30(22): 1905-1908.
[18] Zhu Chengliang*, et al. Dual-triangular filter based on an optimized phase-modulated helical fibre grating. Optics Communications, 2022, 503: 127452.
[19] Zhu Chengliang*, et al. Mode-couplings in two cascaded helical long-period fibre gratings and their application to polarization-insensitive band-rejection filter. Optics Communications, 2018, 423: 81-85.
[20] Zhu Chengliang, et al. Enhanced flat-top band-rejection filter based on reflective helical long-period fiber gratings. IEEE Photonics Technology Letters, 2017, 29(12): 964-966.
*代表性会议论文*
[1] Zhu Chengliang*, et al. “All-fiber flat-top orbital angular momentum mode converter realized by a SMF-based helical grating with phase modulation,” SPIE/COS Photonics Asia, 2021, 11902-23. 【Invited Paper】
[2] Zhu Chengliang*, et al. “Multichannel long-period fiber grating realized by using the helical sampling approach,” International Conference on Nano Electronics Research Education (ICNERE), 2018, P2-2. 【Invited Paper】
[7] Zhu Chengliang*, et al. “High-sensitivity intensity-interrogated temperature sensor based on phase-modulated grating in chalcogenide fiber” International Conference on Optical Fiber Sensors (OFS), 2023, Th6.54.
[8] Zhu Chengliang*, et al. “Wideband and polarization-insensitive band-rejection filter realized by using two cascaded helical long-period fibre gratings” Asia Communications and Photonics Conference (ACP), 2018, 491.
[9] Zhu Chengliang*, et al. “Multichannel helical long-period fiber grating realized by using the DC-sampling approach,” IEICE General Conference, paper: 2019,C-3-12.
[10] Zhu Chengliang*, et al. “All-fiber circular polarization converter based on utilization of two consecutively-cascaded helical long-period gratings,” IEICE Technical Committee on OptoElectronics, 2018, P3-7.
[11] Zhu Chengliang*, et al. “Polarization-independent flat-top band-rejection filter based on utilization of two successively-cascaded helical long-period fiber gratings,” IEICE Society Conference, 2017, C-3-12.
[12] Zhu Chengliang*, et al. “Characterization of a phase-shifted long-period fiber grating by using the imaging method,” IEICE General Conference, 2017, C-3-40.
[13] Zhu Chengliang, et al. “Coherent MPI Measurement method for Short BIF using Pulsed ASE Test Signal with Delay Reflector,” OptoElectronics and Communications Conference (OECC) 2011, 8B2_6.
[14] 朱程亮, et al. “エルビウムドープ光ファイバ増幅器のASEを光源とするOTDRの実験的検討”, 日本電子情報通信学会総合大会, 2011, B-13-36.
【专利】
[1] 朱程亮等, 一种超高信道数光纤轨道角动量模式转换器, 2024, 中国, 202411016475X.
[2] 朱程亮, 超宽带宽光纤边缘滤波器及功率解调传感系统, 2022, 中国, 202210661137.6.
[3] 朱程亮等, 一种新型长周期光纤光栅差分式强度解调传感系统, 2021, 中国, 202111281011.8.
[4] 朱程亮等, 一种同时测量扭转、温度和应变的反射式光纤传感器, 2021, 中国, 202111259735.2.
[5] 李洪谱; 朱程亮, 多チャンネルファイバグレーティング、多チャンネルファイバグレ ーティング製造装置及び多チャンネルファイバグレーティングの製造方法, 2022, 日本, 7182250.
讲授课程情况
本科:《光纤通信》(校一流本科课程)、 《科技文献写作》
硕士:《论文写作指导》(河北省研究生示范课程)、《光纤通信技术》
