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
1. 日本华侨华人博士协会会员
2. 中国光学学会(COS)会员
3. 中国自动化学会终身会员
4. The Institute of Electrical and Electronics Engineers (IEEE) 会员
5. Optica Publishing Group会员
6. Institute of Electronics, Information and Communication Engineers (IEICE)会员
7. MDPI SENSORS, Applied Sciences, Frontiers in Sensors期刊编辑
8. Optics Letters,Optics Express, IEEE/OPTICA Journal of Lightwave Technology,IEEE Transactions on Instrumentation and Measurement, IEEE Photonics Technology Letters,Infrared Physics and Technology, Measurement, Optics Communications,Optical fiber technology等SCI期刊审稿人。
9. 国家自然科学基金通讯评审人
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
1. 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)
2. 2019年度Dean's award for graduate school of science and technology, Shizuoka University. (唯一获奖博士)
3. 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IEEE/COS PGC、SPIE/COS Photonics Asia、SPIE IACOP、SPIE OCOIP、全国光子学学术会议(中国光学学会纤维光学与集成光学专业委员会)等作特邀报告10余次。
【代表性学术论文】
*代表性SCI期刊论文*
[1] Zhu Chengliang*, et al. Femtosecond laser inscribed phase-shifted superstructure FBG and its application to differential-type high refractive index sensor, IEEE/OPTICA Journal of Lightwave Technology, 2025, in press.
[2] Zhu Chengliang*, et al. Submillimeter-length single-helix chiral grating in high-NA fiber for robust third-order OAM generation, Optics Letters, 2025, 50(17), 5270-5273.
[3] Zhu Chengliang*, et al. High-sensitivity and external RI-independent mode-selective Michelson interferometer using a single-ended helical graded-index fiber, IEEE/OPTICA Journal of Lightwave Technology, 2025, 43(11), 5336-5344.
[4] 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.
[5] Zhu Chengliang*, et al. Ultrahigh-channel-count OAM mode conversion utilizing a hybrid few-mode fiber configuration, Optics Letters, 2024, 49(16), 4626-4629.
[6] 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】
[7] 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.
[8] 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.
[9] 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.
[10] 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.
[11] 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.
[12] 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.
[13] 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.
[14] 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.
[15] 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.
[1] 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】
[16] 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.
[17] 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.
[2] 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.
[3] 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.
[4] Zhu Chengliang*, et al. Dual-triangular filter based on an optimized phase-modulated helical fibre grating. Optics Communications, 2022, 503: 127452.
[5] 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.
[6] 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】
[3] Zhu Chengliang*, et al. “Splice-point-twisted helical photonic crystal fiber for strain-compensated directional torsion sensing,” Opto-Electronics and Communications Conference (OECC), 2025, MC1-4.
[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》(东北大学建设课程)
指导研究生情况
毕业生以光学研发岗、自动化研发岗、嵌入式研发岗等入职华为、小米、新凯来等企业;在校期间获得国家奖学金、智冠深奖学金、苏州工业园区奖学金、东北大学一等学业奖学金等。对于志在国际化视野的优秀同学,有能力向交集的国外学术机构直接推荐,包括日本国立静冈大学、日本电气通信大学、日本北海道大学、日本名古屋大学、英国南安普顿大学等。