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罗正钱

系别:电子工程系

职称:教授、博导,电子工程系主任

邮箱:zqluo@xmu.edu.cn

联系方式:0592-2580141

办公地点:九游网站入口官网文宣楼翔安校区B305-4

个人简历:


学习或工作经历

2000-2004 哈尔滨工业大学,理学学士,应用物理学

2004-2009 九游网站入口官网,工学博士,通信与信息系统

2007-2009 新加坡南洋理工大学,联合培养博士,光电子

2010-2017 九游网站入口官网电子工程系, 助理教授/副教授

2015-至今 九游网站入口官网电子工程系,博士生导师

2016-2017 麻省理工学院(MIT),访问学者

2017-至今 九游网站入口官网电子工程系,教授

研究方向

光纤激光技术及应用、非线性光纤光学、片上集成光子器件

主讲课程

光纤通信系统 (本科)

光纤光学(研究生)

学术兼职

(1)福建省超快激光技术及应用重点实验室,主任, 2022-

(2)IEEE高级会员,Senior Member, 2015-

(3)《中国激光》,期刊编委,2024-

(4)《Optical Materials Express》,Lead Guest Editor,2019-2020

(5)Frontiers in Electronic Materials》,Associate Editor,2021-

(6)福建省光学学会副会长, 2018-


成果奖励

(1)国家优秀青年科学基金获得者(2020

(2)福建省自然科学二等奖, 第一完成人 (2020)

(3)福建青年科技奖(2021

(4)福建运盛青年科奖(2022

(5)福建省高层次人才B类(2023

(6)厦门市拔尖人才(2021

(7)中国光学十大进展提名奖(当年全国共20项)(2023

(8)中国光学工程学会—光纤激光五年优秀成果奖(全国共16项)(2023

(9)Elsevier中国高被引学者(2021-至今)

(10)讲授《激光原理与技术》入选国家一流本科课程(2023,排名第3)


近5年主持代表性课题

1.国家自然科学基金重点项目,可见光锁模飞秒光纤激光系统研究及其在可见-紫外光纤光梳的应用,2023/01-2027/12,      281万,主持

2.国家优秀青年科学基金,新波段全光纤超快激光技术及应用,2021/01-2023/12, 120万,主持

3.国家重点研发计划子课题, 星载激光功率放大器系统集成, 2020/12 -2025/12, 211万(项目总经费2202万), 主持

4.国家自然科学基金重大研究计划(培育项目),全光纤可见光超快涡旋激光产生及光场动态调控研究,2018/01-2020/12,78万,主持

5.福建自然科学基金重点项目,片上集成硫系波导中红外飞秒激光源的研究      2022/04-2025/03, 30万元,主持


代表作

[1]H. Lin, Y. Song, Y. Huang, D. Kita, S. Deckoff-Jones, K. Wang, L. Li, J. Li, H. Zheng, Z. Q. Luo, H. Wang, S. Novak, A. Yadav, C. Huang, R. Shiue, D. Englund, T. Gu, D. Hewak, K. Richardson, J. Kong and J. Hu*, “Chalcogenide glass-on-graphene photonics”, Nature Photonics, 11, 798-805, 2017.

[2]J. Zou, C. Dong, H. Wang, T. Du, and Z. Q. Luo*, “Towards visible-wavelength passively mode-locked laser in all-fiber format,” Light: Science & Applications, 9, 61, 2020.

[3]Q. Ruan, X. Xiao, J. Zou, H. Wang, S. Fan, T. Li, J. Li, Z. Dong, Z. Cai, Z. Q. Luo* , “Visible-wavelength spatiotemporal mode-locked fiber laser delivering 9 ps, 4 nJ pulses at 635 nm”, Laser & Photonics Reviews, 16: 2100678, 2022.

[4]J. Zou, Q. Ruan, T. Chen, H. Wang, L. Song, Y. Bu, and Z. Q. Luo*, "635 nm femtosecond fiber laser oscillator and amplifier," Advanced Photonics Nexus 3, 026004, 2024.

[5]Z. Li, Q. Du*, C. Wang, J. Zou, T. Du, K. Richardson, Z. Cai, J. Hu, Z. Q. Luo*, “Externally Pumped Photonic Chip-Based Ultrafast Raman Soliton Source”, Laser & Photonics Reviews, 15(2): 2000301, 2021.

[6]J. Zou, J. Hong, Z. Zhao, Q. Li, Q. Ruan, H. Wang, Y. Bu*, X. Guan, M. Zhou, and Z. Feng, Z. Q. Luo*, "3.6 W compact all-fiber Pr3+-doped green laser at 521 nm," Advanced Photonics 4, 056001, 2022.

[7]J. Zou, T. Li, Y. Dou, J. Li, N. Chen, Y. Bu*, Z. Q. Luo*, “Direct generation of watt-level yellow Dy3+-doped fiber laser”, Photonics Research, 9(4), 446-451, 2021.

[8]T. Li, Z. Wang, J. Zou, J. Hong, Q. Ruan, H. Wang, Z. Dong, and Z. Q. Luo*, "Direct generation of 3.17 mJ green pulses in a cavity-dumped Ho3+-doped fiber laser at 543 nm," Photonics Research. 11, 413-419, 2023.

[9]J. Zou, J. Li, L. Tianran, Y. Huang, Q. Ruan, Y. Dou, and Z. Q. Luo*, “Tunable, continuous-wave, deep-ultraviolet laser generation by intracavity frequency doubling of visible fiber lasers,” Journal of Lightwave Technology, 42, 332-338, 2022.

[10]H. Wang, J. Zou, T. Du, B. Xu, H. Xu, Z. Cai, and Z. Q. Luo*, “High-efficiency, yellow-light Dy3+-doped fiber laser with wavelength tuning from 568.7 to 581.9 nm,” Optics Letters, 44, 4423-4426, 2019.

[11]J. Zou, Q. Ruan, X. Zhang, B. Xu, Z. Cai, and Z. Q. Luo*, “Visible-wavelength pulsed lasers with low-dimensional saturable absorbers,” Nanophotonics, 9, 2273-2294, 2020.

[12]J. Zou, Z. Kang, R. Wang, H. Wang, J. Liu, C. Dong, X. Jiang, B. Xu, Z. Cai, G. Qin, H. Zhang*, Z. Q. Luo*, “Green/red pulsed vortex-beam oscillations in all-fiber lasers with visible-resonance gold nanorods,” Nanoscale, 11, 15991-16000, 2019.

[13]H. Sun, L. Wang, J. Zou, Q. Ruan, Y. Ding, C. Dong, Z. Dong, and Z. Q. Luo*, “Visible-Wavelength All-Fiber Mode-Locked Vortex Laser,” Journal of Lightwave Technology, 40, 191-195, 2022.

[14]J. Hong, J. Zou, Y. Wang*, Q. Ruan, T. Chen, Y. Cheng, Y. Bu, and Z. Q. Luo*, "All-fiber cyan laser at 491.5 nm," Optics Letters 48, 1327-1330, 2023.

[15]X. Zhang, W. Li, J. Li, H. Xu, Z. Cai, and Z. Q. Luo*, “Mid-infrared all-fiber gain-switched pulsed laser at 3 μm,” Opto-Electronic Advances, 3, 190032, 2020.

[16]T. Chen, J. Li, J. Yuan, X. Zhou, Y. Ding, L. Wang, J. Zou, Q. Li, Q. Ruan, and H. Wang, and Z. Q. Luo* "3.5 μm Watt-Level All-Fiber Lasers Based on Mid-IR Dielectric-Coated Fiber Mirrors," Journal of Lightwave Technology, 41, 249-254, 2022.

[17]W. Li, H. Wang, T. Du, B. Xu, Z. Cai, H. Xu, and Z. Q. Luo*, “Compact self-Q-switched, tunable mid-infrared all-fiber pulsed laser,” Optics Express, vol. 26, 34497-34502, 2018.

[18]Y. Li, T. Du, B. Xu, H. Xu, Z. Cai, V. M. Mashinsky, and Z. Q. Luo*, “Compact all-fiber 2.1-2.7 μm tunable Raman soliton source based on germania-core fiber,” Optics Express, vol. 27, 28544-28550, 2019.

[19]T. Du, Z. Q. Luo*, R. Yang, Y. Huang, Q. Ruan, Z. Cai, and H. Xu, "1.2-W average-power, 700-W peak-power, 100-ps dissipative soliton resonance in a compact Er: Yb co-doped double-clad fiber laser," Optics Letters, vol. 42, pp. 462-465, 2017.

[20]Z. Q. Luo, M. Zhong, F. Xiong, D. Wu, Y. Huang, Y. Li, L. Le, B. Xu, H. Xu, and Z. Cai, "Intermode beating mode-locking technique for O-band mixed-cascaded Raman fiber lasers," Optics Letters, 40, 502-505, 2015.


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