George Yuhui Chen (陈宇徽) 特聘教授 深圳大学

国家特聘青年专家，深圳市超快激光微纳制造科学与技术重点实验室的副主任

George Yuhui Chen博士2009年本硕毕业于英国帝国理工学院，2014年在英国南安普顿大学光电子研究中心（ORC）获得博士学位。2013至2015年期间在英国SPI Lasers有限公司与英国南安普顿大学的联合激光研究实验室从事博士后研究工作。2015年加入南澳大学担任研究员，并在建立南澳大利亚大学和山东省科学院之间的一个联合实验室。他曾在MinEx CRC（世界上最大的矿产勘探合作研究中心）从事一个项目。2021年荣获国家第十六批“国家重大人才工程项目”青年项目，加入深圳大学担任特聘教授。2022年任深圳市超快激光微纳制造科学与技术重点实验室的副主任。2017年获得山东省政府“外专项目团队专家”在山东科学院/齐鲁工业大学定期进行英语授课。他专注于光纤物理和化学传感技术的研究，发表了56篇学术论文和10个国际会议受邀学术报告，拥有1项书籍章节和1项发明专利。作为第一作者和通讯作者在相关领域的顶级期刊上如Materials Horizons, Biosensors and Bioelectronics, ACS Sensors发表多篇具有影响力的学术论文。主持和参与多项科研项目其科研经费达3.6百万澳元和 3.5千万元左右。在国际光电子学术领域中，享有一定的国际声誉，自2018年以来担任光纤传感器国际会议（OFS）技术委员会成员，共同主办了该领域最大的学术会议之一。本人在亚洲最大的光子学会议（APC）上创建并主持了一个研讨会。目前担任国际光学期刊Scientific Reports的副主编，Optica和IEEE高级会员。

http://cofs.szu.edu.cn/personDetail/203

https://publons.com/researcher/4835407/george-y-chen

https://0-scholar-google-com.brum.beds.ac.uk/citations?user=mD4P0O8AAAAJ&hl=en

一、教育经历

2009.10-2014.5：博士（PhD）
[英国] University of Southampton, Optoelectronics Research Centre（世界最著名的光电子技术研究中心之一），光电子专业

2005.10-2009.8：学士、硕士（BEng & MEng）
[英国] Imperial College London （QS世界大学排名第6），电子与信息工程专业

二、工作经历

2021.7-至今： 特聘教授（Professor）
深圳大学

§ 广东省光纤传感技术粤港联合研究中心

§ 射频异质异构集成重点实验室

§ 光电子器件与教育部重点实验室

§ 深圳市物联网光子器件与传感系统重点实验室

§ 深圳市发展和改革委员会光学材料飞秒激光制备技术工程实验室

§ 深圳市超快激光微纳制造重点实验室（副主任）

主要研究方向：光纤传感技术

(1) 超远距离分布式光纤振动传感技术：海底地震监测

(2) 光纤化学传感技术：食品/水安全

2019.1-2021.2：高级研究员（Senior Research Fellow）
[澳大利亚] University of South Australia（光电子激光研究中心负责人之一），MinEx CRC （号称是世界上最大的矿产勘探合作）

2015.4-2018.12：研究员（Research Fellow）
[澳大利亚] University of South Australia，从事飞秒激光波导直写及材料加工方向的研究

2013.2-2015.4：博士后（Postdoctoral Research Fellow）
[英国] University of Southampton, 光电研究中心与SPI Lasers公司联合实验室先进激光研究中心，从事光纤缺陷自动检测系统，及折射率传感器的研究

三、人才计划/奖项

1.国家第十六批“国家重大人才工程项目”青年项目（国家特聘青年专家），中共中央组织部，2019.

2.外专项目团队专家，山东省，2017.

3. Optica/Optical Society (OSA) 高级会员.

4. Institute of Electrical and Electronics Engineers (IEEE) 高级会员.

5.早期职业研究员网络奖，$6000 AUD，南澳大学，2015.

四、担任国际学术组织职位

• 会议委员会

1. Technical program committee member of the Optoelectronics Global Conference (OGC), 2021-至今.

2. Technical program committee member of the International Conference on Information Optics and Photonics (CIOP), 2021-至今.

3. Technical program committee member of the Optoelectronics and Communications Conference (OECC), 2021-至今.

4. Technical program committee member of the International Conference on Optical Fibre Sensors (OFS, 光纤传感领域最大的会议之一), 2018- 至今.

5. Technical program committee member of Optical Sensors (OSA), 2018.

6. Technical program committee member of World Congress of the International Measurement Confederation (IMEKO), 2018.

• 国际期刊编辑

1. Review editor of Frontiers in Analytical Science, 2021-至今.

2. Editorial board member of Scientific Reports (Nature), 2019-至今.

3. Guest editor of special issue on “Optical Humidity Measurement: Sensors and Applications” in Sensors (MDPI), 2022.

4. Guest editor of special issue on “Advanced Laser Fabrication for Optical Sensors” in Micromachines (MDPI), 2022.

5. Guest editor of special issue on “Optical Fiber Sensors: Development and Applications”, Sensors (MDPI), 2018.

五、学术期刊文章

• 以第一作者或通讯作者身份发表的期刊文章

(34第一/通讯作者, 8 邀请文章, h-index: 22, 2300+ Google citations, IF 2023)

1. X. Rao, L. Zhao, L. Xu, Y. Wang, K. Liu, Y. Wang, G. Y. Chen*, T. Liu, and Y. Wang, “Review of optical humidity sensors”, Sensors (IF 3.847), vol. 21, no. 23, pp. 8049, 2021. (invited paper)

2. J. Liu, Y. Xing, X. Zhou*, G. Y. Chen*, and H. Shi, “Light-sheet skew rays enhanced U-shaped fiber-optic fluorescent immunosensor for microcystin-LR”, Biosensors and Bioelectronics (IF 12.545), vol. 176, pp. 112902, 2021.

3. G. Y. Chen*, S. Fox, D. G. Lancaster, and S. Soren, “Temperature-compensated interferometric torque sensor with bi-directional coiling”, Journal of Lightwave Technology (IF 4.439), vol. 39, no. 12, pp. 4166–4173, 2021.

4. G. Y. Chen*, J. Wang, and D. G. Lancaster, “Fiber-optic skew ray sensors”, Sensors (IF 3.847), vol. 20, no. 9, pp. 2499–23, 2020.

5. J. Wang, G. Y. Chen*, X. Wu, H. Xu, T. M. Monro, T. Liu, and D. G. Lancaster, “Light-sheet skew-ray-enhanced localized surface plasmon resonance based chemical sensor”, ACS Sensors (IF 9.618), vol. 5, no. 1, pp. 127–132, 2019.

6. G. Y. Chen*, X. Wu, C. A. Codemard, L. Yu, X. Liu, H. Xu*, T. M. Monro, and D. G. Lancaster, “Optical hygrometer using light-sheet skew-ray probed multimode fiber with polyelectrolyte coating”, Sensors and Actuators: B. Chemical (IF 9.221), vol. 296, id. 126685, 2019.

7. G. Y. Chen*, A. François, X. Wu, W. Q. Zhang, C. A. Codemard, H. Xu, T. M. Monro, and D. G. Lancaster, “Light-sheet skew-ray enhanced pump-absorption for sensing”, Journal of Lightwave Technology (IF 4.439), vol. 37, no. 9, pp. 2140–2146, 2019.

8. G. Y. Chen*, X. Wu, E. P. Schartner, S. Shahnia, N. Bourbeau Hébert, L. Yu, X. Liu, S. Afshar V., T. P. Newson, H. Ebendorff-Heidepriem, H. Xu*, D. G. Lancaster, and T. M. Monro, “Short-range non-bending fully distributed water-humidity sensors”, Journal of Lightwave Technology (IF 4.439), vol. 37, no. 9, pp. 2014–2022, 2019.

9. G. Y. Chen*, T. Lee, Y. Q. Kang, T. M. Monro, and D. G. Lancaster, “Double edge-diffraction mediated virtual shadow for distance metrology”, New Journal of Physics (IF 3.746), vol. 20, no. 10, id. 103029, 2018.

10. G. Y. Chen*, F. Piantedosi, D. Otten, Y. Q. Kang, W. Q. Zhang, X. Zhou, T. M. Monro, and D. G. Lancaster, “Femtosecond-laser-written microstructured waveguides in BK7 glass”, Scientific Reports (IF 4.380), vol. 8, id. 10377, 2018.

11. G. Y. Chen*, S. Shahnia, T. M. Monro, and D. G. Lancaster, “Force sensors using skew-ray-probed plastic optical fibers”, IEEE Photonics Journal (IF 2.250), vol. 10, no. 3, id. 6802208, 2018.

12. G. Y. Chen*, D. G. Lancaster, and T. M. Monro, “Optical microfiber technology for current, temperature, acceleration, acoustic, humidity and ultraviolet light sensing”, Sensors (IF 3.847), vol. 18, no. 1, pp. 72–97, 2018. (invited paper)

13. G. Y. Chen*, X. Wu, Y. Q. Kang, L. Yu, T. M. Monro, D. G. Lancaster, X. Liu*, and H. Xu*, “Ultra-fast hygrometer based on U-shaped optical microfiber with nanoporous polyelectrolyte coating”, Scientific Reports (IF 4.380), vol. 7, pp. 7943, 2017.

14. G. Y. Chen*, D. Otten, Y. Q. Kang, T. M. Monro, and D. G. Lancaster, “Measuring the radial position of defects within optical fibers using skew rays”, Journal of Sensors (IF 2.336), vol. 2017, id. 4879528, 2017. (invited paper)

15. X. Wu, J. Xu, G. Y. Chen*, R. Fan, X. Liu, and H. Xu*, “Harvesting, sensing and regulating light based on photo-thermal effect of Cu@CuO mesh”, Green Energy & Environment (IF 12.781), vol. 2, no. 4, pp. 387–392, 2017.

16. G. Y. Chen*, X. Wu, X. Liu, D. G. Lancaster, T. M. Monro, and H. Xu*, “Photodetector based on Vernier-enhanced Fabry-Perot interferometers with a photo-thermal coating”, Scientific Reports (IF 4.380), vol. 7, pp. 41895, 2017.

17. L. Yu, H. Xu, T. M. Monro, D. G. Lancaster, Y. Xie, H. Zeng, G. Y. Chen*, and X. Liu*, “Ultrafast colorimetric humidity-sensitive polyelectrolyte coating for touchless control”, Materials Horizons (IF 15.717), vol. 4, no. 1, pp. 72–82, 2017. (featured by MRS Bulletin, recommended by RSC, inside cover of Materials Horizons)

18. G. Y. Chen*, C. A. Codemard, M. N. Zervas, T. M. Monro, and D. G. Lancaster, “Enhanced pump absorption of active fiber components with skew rays”, Journal of Lightwave Technology (IF 4.439), vol. 34, no. 24, pp. 5652–5650, 2016.

19. G. Y. Chen*, T. M. Monro, and D. G. Lancaster, “Detection of microscopic defects in optical fiber coatings using angle-resolved skew rays”, Optics Letters (IF 3.776), vol. 41, no. 17, pp. 4036-4039, 2016.

20. G. Y. Chen*, C. A. Codemard, P. M. Gorman, J. S. Chan, and M. N. Zervas, “Angle-resolved characterization and ray-optics modeling of fiber-optic sensors”, Journal of Lightwave Technology (IF 4.439), vol. 33, no. 24, pp. 5210–5217, 2015.

21. G. Y. Chen* and Z. Wang, “Towards extremely sensitive ultraviolet-light sensors employing photochromic optical microfiber”, Journal of Sensors (IF 2.336), vol. 2015, id. 586318, 2015. (invited paper)

22. G. Y. Chen*, C. A. Codemard, R. J. Lewis, L. Jankowski, J. S. Chan, P. M. Gorman, and M. N. Zervas, “Enhanced responsivity with skew ray excitation of reflection- and transmission-type refractometric sensors”, Optics Letters (IF 3.776), vol. 39, no. 13, pp. 3822-3825, 2014.

23. G. Y. Chen* and T. P. Newson, “Detection bandwidth of fiber-optic current sensors based on the Faraday Effect”, Electronics Letters (IF 1.202), vol. 50, no. 8, pp. 626–627, 2014.

24. G. Y. Chen, M. Ding, T. P. Newson, and G. Brambilla*, “A review of microfiber and nanofiber based optical sensors”, Open Optics Journal, vol. 7, pp. 32–57, 2013. (invited paper)

25. G. Y. Chen*, T. P. Newson, and G. Brambilla, “Optical microfibers for fast current sensing”, Optical Fiber Technology (IF 2.800), vol. 19, no. 6B, pp. 802–807, 2013. (invited paper)

26. G. Y. Chen*, T. P. Newson, and G. Brambilla, “Birefringence treatment of non-ideal optical microfibre coils for continuous Faraday rotation”, Electronics Letters (IF 1.202), vol. 49, no. 11, pp. 714–715, 2013. (featured by Electronics Letters)

27. G. Y. Chen*, G. Brambilla, and T. P. Newson, “Inspection of electrical wires for insulation faults and current surges using sliding temperature sensor based on optical microfibre coil resonator”, Electronics Letters (IF 1.202), vol. 49, no. 1, pp. 46–47, 2013.

28. G. Y. Chen*, G. Brambilla, and T. P. Newson, “Efficient Faraday rotation in birefringent optical microfibre loop resonators for current sensing”, Electronics Letters (IF 1.202), vol. 48, no. 24, pp. 1547–1548, 2012. (highlighted by Electronics Letters)

29. G. Y. Chen*, G. Brambilla, and T. P. Newson, “Compact acoustic sensor based on air-backed mandrel coiled with optical microfiber”, Optics Letters (IF 3.776), vol. 37, no. 22, pp. 4720-4722, 2012.

30. G. Y. Chen*, G. Brambilla, and T. P. Newson, “Spun optical microfiber”, IEEE Photonics Technology Letters (IF 2.414), vol. 24, no. 19, pp. 1663-1666, 2012.

31. G. Y. Chen*, X. Zhang, G. Brambilla, and T. P. Newson, “Temperature compensation techniques for resonantly enhanced sensors and devices based on optical microcoil resonators”, Optics Communications (IF 2.335), vol. 285, no. 23, pp. 4677-4683, 2012. (invited paper)

32. G. Y. Chen*, X. Zhang, G. Brambilla, and T. P. Newson, “Enhanced responsivity of a flexural disc acceleration sensor based on optical microfiber”, Optics Communications (IF 2.335), vol. 285, no. 23, pp. 4709-4714, 2012. (invited paper)

33. G. Y. Chen*, T. Lee, R. Ismaeel, G. Brambilla, and T. P. Newson, “Resonantly enhanced Faraday rotation in an microcoil current sensor”, IEEE Photonics Technology Letters (IF 2.414), vol. 24, no. 10, pp. 860-862, 2012.

34. G. Y. Chen*, X. Zhang, G. Brambilla, and T. P. Newson, “Theoretical and experimental demonstrations of a microfiber-based flexural disc accelerometer”, Optics Letters (IF 3.776), vol. 36, no. 18, pp. 3669-3671, 2011.

以合作作者身份发表的期刊文章

1. J. Tan, L. Liu, F. Li, Z. Chen, G. Y. Chen, F. Fang, J. Guo, M. He, and X. Zhou*, “Screening of endocrine disrupting potential of surface waters via an affinity-based biosensor in a rural community in the yellow river basin, China”, Environmental Science & Technology (IF 11.357), 2022. (front cover of Environmental Science & Technology)

2. H. Khosropour*, P. K. Kalambate, R. P. Kalambate, K. Permpoka, X. Zhou, G. Y. Chen, and W. Laiwattanapaisal*, “A comprehensive review on electrochemical and optical aptasensors for organophosphorus pesticides”, Microchimica Acta (IF 6.408), vol. 189, pp. 362, 2022.

3. B. Xue, Q. Yang, K. Xia, Z. Li, G. Y. Chen, D. Zhang*, and X. Zhou*, “An AuNPs/mesoporous NiO/nickel foam nanocomposite as a miniaturized electrode for heavy metal detection in groundwater”, Engineering (IF 12.834), 2022.

4. Y. Xing, B. Xue, P. Qi*, G. Y. Chen, X. Zhou, “A rapid and sensitive fluorescence biosensor for Hg²⁺ detection in environmental samples”, Sensors and Actuators Reports, vol. 4, pp. 100101, 2022.

5. W. Niu, G. Y. Chen, H. Xu, X. Liu*, and J. Sun, “Highly transparent and self-healable solar thermal anti-/de-Icing surfaces: when ultrathin MXene multilayers marry solid slippery self-cleaning coating”, Advanced Materials (IF 32.086), vol. 34, no. 10, pp. 2108232, 2022.

6. M. Khalid*, G. Y. Chen, H. Ebendorf-Heidepreim, D. G. Lancaster, “Femtosecond laser induced low propagation loss waveguides in a lead-germanate glass for efficient lasing in near to mid-IR”, Scientific Reports (IF 4.380), vol. 11, pp. 10742, 2021.

7. Y. Wang, X. Wu, T. Gao, Y. Lu, X. Yang, G. Y. Chen, G. Owens, and H. Xu*, “Same materials, bigger output: a reversibly transformable 2D-3D photothermal evaporator for highly efficient solar steam generation“, Nano Energy (IF 19.069), vol. 79, pp. 105477, 2020.

8. B. Shao, Y. Wang, X. Wu, G. Y. Chen, G. Owens, and H. Xu*, “Stackable nickel-cobalt@polydopamine nanosheet based photothermal sponges for highly efficient solar steam generation”, Journal of Materials Chemistry A (IF 14.511), vol. 8, no. 23, pp. 11665–11673, 2020.

9. J. Zhu, G. Y. Chen, L. Yu, H. Xu, X. Liu*, and J. Sun, “Mechanically strong and highly stiff supramolecular polymer composites repairable at ambient conditions”, CCS Chemistry, vol. 2, no. 4, pp. 280–292, 2020.

10. D. G. Lancaster*, D. Otten, A. Cenescu, N. Bourbeau Hébert, G. Y. Chen, M. C. Johnson, T. M. Monro, J. Genest, “An ultra-stable 2.9 μm guided-wave infrared chip laser and application to nano-spectroscopy”, APL Photonics (IF 6.382), vol. 4, pp. 110802, 2019.

11. M. Khalid*, G. Y. Chen, J. Bei, H. Ebendorff-Heidepriem, and D. G. Lancaster, “Microchip and ultra-fast laser inscribed waveguide lasers in Yb3+ germanate glass”, Optical Materials Express (IF 3.442), vol. 9, no. 8, pp. 3557–3564, 2019.

12. X. Wu, G. Y. Chen, G. Owens, D. Chu, and H. Xu*, “Photothermal materials: a key platform enabling highly efficient water evaporation driven by solar energy”, Materials Today Energy (IF 9.257), vol. 12, pp. 277–296, 2019.

13. X. Wu, L. Wu, J. Tan, G. Y. Chen, G. Owens, and H. Xu*, “Evaporation above a bulk water surface using an oil lamp inspired highly efficient solar-steam generation strategy”, Journal of Materials Chemistry A (IF 14.511), vol. 6, no. 26, pp. 12267–12274, 2018.

14. N. Bourbeau Hébert*, D. G. Lancaster, V. Michaud-Belleau, G. Y. Chen, and J. Genest, “Highly coherent free-running dual-comb chip platform”, Optics Letters (IF 3.776), vol. 43, no. 8, 1814–1817, 2018.

15. F. Piantedosi*, G. Y. Chen, T. M. Monro, and D. G. Lancaster, “Widely tunable, high slope efficiency waveguide lasers in a Yb-doped glass chip operating at 1 μm”, Optics Letters (IF 3.776), vol. 43, no. 8, 1902–1905, 2018.

16. C. Khurmi*, S. Thoday, T. M. Monro, G. Y. Chen, and D. G. Lancaster, “Visible laser emission from a praseodymium-doped fluorozirconate guided-wave chip”, Optics Letters (IF 3.776), vol. 42, no. 17, pp. 3339–3342, 2017.

17. N. Bourbeau Hébert, J. Genest*, J. Deschênes, G. Bergeron, G. Y. Chen, C. Khurmi, and D. G. Lancaster, “Self-corrected chip-based dual-comb spectrometer”, Optics Express (IF 3.894), vol. 25, no. 7, pp. 8168–8179, 2017.

18. X. Wu, G. Y. Chen, W. Zhang, X. Liu*, H. Xu*, “A Plant-transpiration-process-inspired strategy for highly efficient solar evaporation”, Advanced Sustainable Systems (IF 6.737), vol. 1, no. 6, pp. 1700046, 2017. (front cover of Advanced Sustainable Systems)

19. C. Khurmi*, N. B. Hébert, W. Q. Zhang, S. Afshar V., G. Y. Chen, J. Genest, T. M. Monro, and D. G. Lancaster, “Ultrafast pulse generation in a mode-locked Erbium chip waveguide laser”, Optics Express (IF 3.894), vol. 24, no. 24, pp. 27166–27176, 2016.

20. L. Yu, G. Y. Chen, H. Xu, and X. Liu*, “Substrate-independent, transparent oil-repellent coatings with self-healing and persistent easy-sliding oil-repellency”, ACS Nano (IF 18.027), vol. 10, no. 1, pp. 1073–1085, 2016.

21. K. He, H. Duan, G. Y. Chen, X. Liu*, W. Yang, and D. Wang, “Cleaning of oil fouling with water enabled by Zwitterionic polyelectrolyte coatings: overcoming the imperative challenge of oil-water separation membranes”, ACS Nano (IF 18.027), vol. 9, no. 9, pp. 9188–9198, 2015.

22. X. Zhang*, M. Belal, G. Y. Chen, Z. Q. Song, G. Brambilla, and T. P. Newson, “Compact optical microfiber phase modulator”, Optics Letters (IF 3.776), vol. 37, no. 3, pp. 320–322, 2011.

六、国际会议特邀报告

1. G. Y. Chen*, “Light-sheet skew rays based chemical sensors”, Optoelectronics Global Conference, 2022.

2. G. Y. Chen*, “Integrated and fiber-optic humidity sensing”, 中国光纤传感大会会议 (OFS-China), 2022.

3. G. Y. Chen*, “Vortex light pipe for environmental sensing”, 13th International Conference on Information Optics and Photonics, 2022.

4. G. Y. Chen*, “Ultra-sensitive and ultra-fast humidity sensors”, International Conference on Advanced Optical Manufacturing Technologies & Applications 2022 & 2nd International Forum of Young Scientists on Advanced Optical Manufacturing, 2022.

5. G. Y. Chen*, “Resolving elusive defects in optical fiber coatings”, Optoelectronics Global Conference, 2021.

6. G. Y. Chen* and D. G. Lancaster, “Sensitized light pipes: multimode fibers empowered by skew rays”, Optical Sensors and Sensing Congress, pp. STh5A.2, 2019.

7. G. Y. Chen*, X. Wu, L. Yu, H. Xu, X. Liu, T. M. Monro, and D. G. Lancaster, “Recent progress in advanced humidity sensors”, XXII World Congress of the International Measurement Confederation, 2018. (sponsored)

8. G. Y. Chen*, “Extremely fast and ultra-sensitive hygrometers for sensing and touchless control”, 7^th International Multidisciplinary Conference on Optofluidics, 2017.

9. G. Y. Chen*, “Recent progress in physical sensing with optical microfiber technology”, 7^th International Photonics and OptoElectronics Meetings, pp. OTh4A.4, 2014. (sponsored)

10. G. Y. Chen, T. Lee, R. Ismaeel, M. Belal, T. P. Newson, and G. Brambilla*, “Optical microfiber sensors for the detection of current pulses", Advanced Photonics Congress, pp. JW2A.3, 2012.

七、会议研讨会主持人

1. Asia Communications and Photonics Conference (ACP) & International Conference on Information Photonics and Optical Communications (IPOC), 2022, Workshop 8: What is the Role of Optical Sensors in Building Smart Environments? http://www.acp2022.org/w8.html

八、章节

1. G. Y. Chen and G. Brambilla, “Optical microfiber physical sensors” in “Optical fiber sensors: advanced techniques and applications”, CRC press, ch. 8, ISBN: 9781482228250, 2015.

九、专利

1. 刘小孔, 乔治·宇辉陈 （George Yuhui Chen）, 余利, 徐浩兰,“湿度传感器及其用途”, 2017.03.30, 201780034024.0, 2021.11.19, CN 109313120 B.

十、媒体访谈

1.湿度传感技术接受德国国家电台采访, September 2018.
https://ondemand-mp3.dradio.de/file/dradio/2018/12/04/spukhafter_touchscreen_feuchtigkeitssensor_ermoeglicht_dlf_
201812041640_ffe70634.mp3 (dubbed)

十一、科研项目 (363万澳元，3508万元)

• 国内主持

1.鹏程孔雀计划：深大高端人才科研启动经费（827/000761），“用于环境监测的高性能多参数传感技术”，深圳市科技创新委员会/深圳大学，499万元，2023.01-2025.12.

2.面上项目（62275172）, “基于螺旋光片LSPR增强荧光机理的光纤食品安全检测技术”，国家自然科学基金委员会, 59万元，2023.01-2026.12.

3.特聘教授科研启动基金，“分布式声音传感器”，深圳大学，100万元，2021.09-2023.08.

4.国家第十六批“国家重大人才工程项目”青年项目（国家特聘青年专家）, 中共中央组织部, 350万元左右，2021.07-2026.06.

• 国内参与

5.孔雀团队计划：高层次人才创新创业计划团队（核心成员），“智能生物传感的应用与研究”，深圳市科技创新委员会，1500万元，2023.01-2027.12.

6.深圳市超快激光微纳制造重点实验室（副主任，ZDSYS20220606100405013），深圳市科技创新委员会，500万元，2023.03-2025.03.

7.光明实验室（1003-30108），“极端环境光纤传感技术”，深圳市科技创新委员会，200万元，2021.10-2024.10.

8.国家重点研发计划项目“政府间国际科技创新合作”等重点专项（SQ2021YFE010025）, “高速飞行器多物理场光纤实时健康监测技术”，中国和日本政府间科技联委会项目，中华人民共和国科学技术部, 300 万元, 2022.01-2024.12.

• 国外主持

9. China-Australia joint research lab, “Chemical, humidity and acoustic sensing”, Minister for Trade, Tourism and Investment (South Australia), 91.6万澳元, 2018.10-2021.02.

10. ForestrySA seed grant, “Plantation soil moisture measurement using a distributed humidity sensor”, ForestrySA Corp., 2万澳元, 2018.08-2019.06.

11. FII Infrastructure Access Scheme, “Laser-engineered masks”, South Australian Government, 1.15万澳元, 2017.06-2017.12.

12. RTIS Seed Grant, “Integrated super-fast humidity detection and smart humidity control”, Shanghai Energy Saving Technology Co. Ltd. & University of South Australia, 4.6万澳元, 2016.08-2017.12.

13. Seed grant, “Optofluidic devices”, Tsinghua University, 2.1万澳元, 2016.01-2017.12.

• 国外参与

14. Project 2, “Coiled Tubing drilling for the definition of mineral deposits”, MinEx CRC, 216.6万澳元 (phase 1/3), 2019.09-2020.09.

15. Transforming Industry Manufacturing Enabler, “The use of machine learning to develop preventive maintenance strategy for linear water assets by integrating a fully distributed optical fibre sensor for real-time non-destructive condition assessment”, University of South Australia, 4万澳元, 2018.08-2019.02.

16. RTIS Development Grant, “Portable solar-steam generation system for clean water supply”, Heilong Jiang Huasheng Graphite Stock Co. Ltd. & University of South Australia, 30.6万澳元, 2017.10-2020.12.

17. Research Grant, “High power durability of soft glasses for laser applications” (FA2386-16-1-4068), Asian Office of Aerospace, Research and Development, 10.3万澳元, 2016.06-2018.06.