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陈鹭剑

系别:电子工程系

职称:教授、博导,电子工程系副主任

邮箱:lujianchen@xmu.edu.cn

联系方式:0592-2580141

办公地点:博鱼体育登录翔安校区文宣楼B305-5

个人简历:


学历:

浙江大学工学学士,材料科学与工程(2002

浙江大学工学博士,材料科学与工程(2007


研究方向:

液晶光子学(液晶光场调控、液晶全息、液晶传感等)、微流控技术(液滴微流控、光流控、声流控等)、动态响应软执行器(液晶弹性体、增材制造技术等)


主讲课程:

光电显示(本科生课)

程序设计实践(本科生课)

有机光电子材料与器件(研究生课)

光电信息功能材料(研究生课)


学术兼职:

浙江大学硅材料国家重点实验室客座研究人员,2010-2012,2015-2017

哈佛大学工程与应用物理学院访问学者,2012.07-2013.07

Displays》编委,2018.06-至今

《液晶与显示》青年编委,2020.05-至今

Responsive Materials》青年编委,2023.11-至今

《液晶与显示》中国液晶青年学者专栏专栏(https://mp.weixin.qq.com/s/sPH4fyw37qTW4BBx2AgSog)客座主编,2023.1

Light Sci. Appl.、Adv. Mater.、Adv. Func. Mater.、Adv. Optical Mater.、Laser Photonics Rev.、Photon. Res.、ACS Photon.、ACS Appl. Mater. Inter.、Opt. Lett.、Opt. Express等期刊审稿人


成果奖励:

福建省高等学校新世纪优秀人才支持计划(2018


课题项目:

1. 液晶几何相位全息复用光学的化学与生物传感研究,国家自然科学基金面上项目,2025/01-2028/12,主持

2. 介晶序构多维操控与多自由度光子调控原理性器件(牵头:华东理工大学,纳米前沿专项,项目名称:介晶纳米构建、编辑及多自由度光场动态调控及应用),国家重点研发计划课题,2023/05-2028/04,主要参与/子课题负责人

3. 基于光流控的动态可重构手性液晶宽带反射型几何相位研究,国家自然科学基金面上项目,2021/01-2024/12,主持

4. 高通量DNA生物合成微流控模块研发(牵头:湖南大学,合成生物学专项,项目名称:新一代DNA合成技术),国家重点研发计划课题,2020/01-2024/12,主要参与

5. 胆甾相液晶微激光器的多功能化构筑及结构与性能关系研究,国家自然科学基金面上项目,2017/01-2020/12,主持

6. 胆甾相液晶螺旋超结构的光配向图案化研究,福建省自然科学基金面上项目,2017/04-2020/03,主持

7. 氧化锌基掺杂型液晶空间光相位调制器的关键技术研究,深圳市基础研究(自由探索)项目,2017/07-2019/06,主持

8. 金属有机骨架薄膜的图案化及应用,浙江大学硅材料国家重点实验室开放课题,2015/07-2017/06,主持

9. 光配向诱导胆甾相液晶螺旋超结构的制备研究,南京大学固体微结构物理国家重点实验室开放课题,2015/06-2017/06,主持

10. 胆甾相液晶核壳结构的微流控制备及可调谐全向激光发射研究,博鱼体育登录中央高校基本科研业务费,2014/01-2016/12,主持

11. 有机-无机杂化免标记型生物传感器的软刻蚀法制备,浙江大学硅材料国家重点实验室开放课题,2010/07-2012/06,主持

12. 基于波导分布反馈技术的固态染料随机激光介质研究,国家自然科学基金青年项目,2009/01-2011/12,主持


学术论文(通讯及第一作者,2014-2024):

1. Wu, K. H.; Zhu. L. T.; Xiao F. F.; Hu, X.; Li, S. S.*; Chen, L. J.*, Light-regulated soliton dynamics in liquid crystals, Nature Communications 2024, 15, 7217. https://news.xmu.edu.cn/info/1045/480211.htm

2. Li, S. L.; Chen, Z. Y.; Chen, P.; Hu, W.; Huang, C.; Li, S. S.; Hu, X.; Lu, Y. Q.*; Chen, L. J.*, Geometric phase-encoded stimuli-responsive cholesteric liquid crystals for visualizing real-time remote monitoring: Humidity sensing as a proof of concept. Light: Science & Applications 2024, 13 (1), 27. https://mp.weixin.qq.com/s/ap1XEY2iIV8b1NbxM0jLuw

3. Gao, X.; Li, D.; Zhao, S.; Yang, D.; Wu, Q.; Li, S. S.; Zhang, L.; Chen, L. J.*; Yang, Y.*; Hu, X.*, Acoustic controllable spatiotemporal cell micro-oscillation for the non-invasive intracellular drug delivery, Analytical Chemistry 2024, DOI: 10.1021/acs.analchem.4c03187

4. Lin, J. Z.; Wu, A. J.; Zhu, L. T.; Wu, K. H.; Li, S. S.*; Chen, L. J.*, Fission of quasi-static dissipative solitons in chiral nematics. Giant 2024, 19, 100312.

5. Hu, X.; Zheng, J.; Zhu, Q.; Wu, Q.; Li, S. S.; Yang, Y.*; Chen, L. J.*, Acoustic assembly and scanning of superlens arrays for high-resolution and large field-of-view bioimaging. ACS Nano 2024, 18 (23), 15218-15228.

6. Lei, B.; Wen, Z. Y.; Wang, H. K.; Gao, J.*; Chen, L. J.*, Bioinspired jumping soft actuators of the liquid crystal elastomer enabled by photo-mechanical coupling. ACS Applied Materials & Interfaces 2024, 16 (1), 1596-1604.

7. Li, W.*; Mi W.; Chen, L. J.*, Advances, challenges and prospects of visible fiber lasers in display technologies, Displays 2024, 82, 102630.

8. Zhu, S. k.; Zheng, Z. h.; Meng, W.; Chang, S. s.; Tan, Y.; Chen, L. J.*; Fang, X.*; Gu, M.; Chen, J. h.*, Harnessing disordered photonics via multi-task learning towards intelligent four-dimensional light field sensors. PhotoniX 2023, 4 (1), 26.

9. Wu, Q.; Pan, C.; Shi, P.; Zou, L.; Huang, S.; Zhang, N.; Li, S. S.; Chen, Q.; Yang, Y.; Chen, L. J.*; Hu, X.*, On-demand transdermal drug delivery platform based on wearable acoustic microneedle array. Chemical Engineering Journal 2023, 477, 147124. https://mp.weixin.qq.com/s/FyOR4SRU3QYnKzE6LVBt3A

10. Wu, K. H.; Chen, C. Q.; Shen, Y.; Cao, Y.; Li, S. S.*; Dierking, I.; Chen, L. J.*, Trajectory engineering of directrons in liquid crystals via photoalignment. Soft Matter 2023, 19 (24), 4483-4490.

11. Lei, B.; Wang, H. K.; Wu, K. H.; Gao, J.*; Chen, L. J.*, Light-driven folding liquid crystal elastomer catapult with improved morphing velocity. Advanced Intelligent Systems 2023, 5 (3), 2200360.

12. Hu, X.; Lei, B.; Li, S. S.; Chen, L. J.*; Li, Q.*, Living cell-laden hydrogels: Unleashing the future of responsive biohybrid systems. Responsive Materials 2023, 1 (1), e20230009.

13. Li, S. L.; Wang, S. H.; Luo, W. C.; You, L. Q.; Li, S. S.*; Chen, L. J.*, Optofluidic tunable broadband distributed bragg reflector based on liquid crystal polymer composites. Optics Express 2022, 30 (19), 33603-33612.

14. Hu, X.; Zheng, J.; Hu, Q.; Liang, L.; Yang, D.; Cheng, Y.; Li, S. S.; Chen, L. J.*; Yang, Y.*, Smart acoustic 3d cell construct assembly with high-resolution. Biofabrication 2022, 14 (4), 045003. https://mp.weixin.qq.com/s/m0MbXo-AQR8Ohna6pFrxFw

15. Cao, Y.; Chong, L.; Wu, K. H.; You, L. Q.; Li, S. S.; Chen, L. J.*, Dynamic coloration of polymerized cholesteric liquid crystal networks by infiltrating organic compounds. Chinese Optics Letters 2022, 20 (9), 091602. https://mp.weixin.qq.com/s/i9PjsqJpbzrcJqpbNPhqWA

16. Chen, H. Q.; Wang, X. Y.; Bisoyi, H. K.; Chen, L. J.*; Li, Q.*, Liquid crystals in curved confined geometries: Microfluidics bring new capabilities for photonic applications and beyond [invited]. Langmuir 2021, 37 (13), 3789-3807.

17. Shan, Y. W.; You, L. Q.; Bisoyi, H. K.; Yang, Y. J.; Ge, Y. H.; Che, K. J.; Li, S. S.; Chen, L. J.*; Li, Q.*, Annular structural colors from bowl-like shriveled photonic microshells of cholesteric liquid crystals. Advanced Optical Materials 2020, 8 (20), 2000692. https://mp.weixin.qq.com/s/TiK0-jBn7_KwrrTebT4nRQ

18. Luo, W. C.; Xu, Y. D.; Yu, G. X.; Li, S. S.; Li, H. Y.; Chen, L. J.*, Reconfigurable polymer-templated liquid crystal holographic gratings via visible-light recording. Optics Express 2020, 28 (12), 17307-17319.

19. Ge, Y. H.; Lan, Y. M.; Li, X. R.; Shan, Y. W.; Yang, Y. J.; Li, S. S.*; Yang, C.; Chen, L. J.*, Polymerized cholesteric liquid crystal microdisks generated by centrifugal microfluidics towards tunable laser emissions [invited, Editors’ Pick]. Chinese Optics Letters 2020, 18 (8), 080006. https://mp.weixin.qq.com/s/1HSOFbJ9_Wv9TwS4WNpsOg

20. Jiang, R. G.; Luo, W. C.; Ge, Y. H.; Wang, X. Z.; Li, S. S.*; Chen, L. J.*, Real-time generation of dynamically patterned cholesteric liquid crystal fingerprint textures based on photoconductive effect. Optics Express 2019, 27 (8), 11462-11471.

21. Che, K. J.; Yang, Y. J.; Lin, Y. L.; Shan, Y. W.; Ge, Y. H.; Li, S. S.; Chen, L. J.*; Yang, C. J., Microfluidic generation of cholesteric liquid crystal droplets with an integrative cavity for dual-gain and controllable lasing. Lab on a Chip 2019, 19 (18), 3116-3122.

22. Shen, Y.; Xu, Y. C.; Ge, Y. H.; Jiang, R. G.; Wang, X. Z.; Li, S. S.*; Chen, L. J.*, Photoalignment of dye-doped cholesteric liquid crystals for electrically tunable patterns with fingerprint textures. Optics Express 2018, 26 (2), 1422-1432.

23. Lin, Y. L.; Gong, L. L.; Che, K. J.; Li, S. S.; Chu, C. X.; Cai, Z. P.; Yang, C. J.; Chen, L. J.*, Competitive excitation and osmotic-pressure-mediated control of lasing modes in cholesteric liquid crystal microshells. Applied Physics Letters 2017, 110 (22), 223301.

24. Lin, Y. L; Yang, Y. J.; Shan, Y. W.; Gong, L. L.; Chen, J. Z.; Li, S.; Chen, L. J.*, Magnetic nanoparticle-assisted tunable optical patterns from spherical cholesteric liquid crystal bragg reflectors. Nanomaterials 2017, 7 (11), 376.

25. Li, W. S.; Shen, Y.; Chen, Z. J.; Cui, Q.; Li, S. S.; Chen, L. J.*, Demonstration of patterned polymer-stabilized cholesteric liquid crystal textures for anti-counterfeiting two-dimensional barcodes. Applied Optics 2017, 56 (3), 601-606.

26. Li, S. S.; Shen, Y.; Chang, Z. N.; Li, W. S.; Xu, Y. C.; Fan, X. Y.; Chen, L. J.*, Dynamic cholesteric liquid crystal superstructures photoaligned by one-step polarization holography. Applied Physics Letters 2017, 111 (23), 231109.

27. Li, W. S.; Ma, L. L.; Gong, L. L.; Li, S. S.; Yang, C.; Luo, B.; Hu, W.; Chen, L. J.*, Interlaced cholesteric liquid crystal fingerprint textures via sequential UV-induced polymer-stabilization. Optical Materials Express 2016, 6 (1), 19-28.

28. Chen, L. J.*; Gong, L. L.; Lin, Y. L.; Jin, X. Y.; Li, H. Y.; Li, S. S.; Che, K. J.; Cai, Z. P.; Yang, C. J., Microfluidic fabrication of cholesteric liquid crystal core-shell structures toward magnetically transportable microlasers. Lab on a Chip 2016, 16 (7), 1206-13.

29. Chen, L. J.*.; Luo, B.; Li, W. S.; Yang, C.; Ye, T.; Li, S. S.; Wang, X. Z.; Cui, Y. J.; Li, H. Y.; Qian, G. D., Growth and characterization of zeolitic imidazolate framework-8 nanocrystalline layers on microstructured surfaces for liquid crystal alignment. RSC Advances 2016, 6 (9), 7488-7494.

30. Yang, C.; Li, S. S.; Li, W. S.; Zuo, H. J.; Chen, L. J.*; Zhang, B. P.; Cai, Z. P., Topologically patterning of polyvinyl alcohol microstructures for vertical-/hybrid-aligned nematic liquid-crystal gratings doped with polyhedral oligomeric silsesquioxane nanoparticles. Chinese Optics Letters 2015, 13 (8), 081603.

31. Ma, L. L.; Li, S. S.; Li, W. S.; Ji, W.; Luo, B.; Zheng, Z. G.; Cai, Z. P.; Chigrinov, V.; Lu, Y. Q.; Hu, W.*; Chen, L. J.*, Rationally designed dynamic superstructures enabled by photoaligning cholesteric liquid crystals. Advanced Optical Materials 2015, 3 (12), 1691-1696.

32. Wang, Z. Y.; Yang, C.; Li, W. W.; Chen, L. J.*; Wang, X. Z.; Cai, Z. P., Dye-concentration-dependent lasing behaviors and spectral characteristics of cholesteric liquid crystals. Applied Physics B 2014, 115 (4), 483-489.

33. Li, W. S.; Yang, C.; Luo, B.; Wang, Z. Y.; Wang, X. Z.; Bu, Y.; Li, S.; Xu, H.; Chen, L. J.*, Effect of preparation parameters on the performance of polymer-stabilized cholesteric liquid crystals for laser emission. Chinese Optics Letters 2014, 12 (11), 111602.

34. Li, S. S.*; Chen, L. J.*; Dong, X. P.; Ren, X. C.; Zhang, X. S.; Liu, S., Spatial frequency doubling with two-step technique. Optics Letters 2014, 39 (7), 2024-2027.

35. Chen, L. J.; Li, Y. N.; Fan, J.; Bisoyi, H. K.; Weitz, D. A.; Li, Q.*, Photoresponsive monodisperse cholesteric liquid crystalline microshells for tunable omnidirectional lasing enabled by a visible light-driven chiral molecular switch. Advanced Optical Materials 2014, 2 (9), 845-848.


期刊封面:

  

著作:

撰写学术章节3章:《Photoactive Functional Soft Materials》(Wiley-VCH,2018)、《液晶光子学》(电子工业出版社,2018)、《液晶自组装及其应用》(科学出版社,2021


课题组欢迎光电、电子、物理、材料等专业背景的博士生和硕士生的加入,也欢迎有继续深造意向的本科生进入实验室进行毕业设计和大创课题研究。



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