宋潮龙
教授,博导 ,湖北省人才计划入选者
性别:男 出生年月:1984年12月
民族:汉 学历:研究生 学位:博士
毕业院校:新加坡南洋理工大学 职称:教授
联系邮箱:songcl@cug.edu.cn
办公室:教二楼 331
主要经历:
2016.12至今:bet36365路检测中心(武汉),bet36365路检测中心,教授,博导
2014.10-2016.11: 劳斯莱斯驻新加坡南洋理工大学研发中心,博士后
2012.10-2014.9:美国佛罗里达大学,生物医学工程学院,博士后
2007.8-2012.8:新加坡南洋理工大学,机械与宇航工程学院,博士
2003.9-2007.6:华中科技大学,光电子科学与工程学院,本科
研究兴趣方向:
微流控芯片先进控制技术:采用三维全息机器视觉技术实时获取微流体动力学参数,并通过反馈控制系统完成微流液滴的生成、停滞、融合以及分类等精准操控。
先进光学成像与检测技术:采用定量相位显微成像、光声显微成像技术等技术高通量获取微流芯片中待测细胞的功能性参数,并用于单细胞的基因表达与表型分析。
电解水制氢装备关键技术:基于微型结构中的气-液多相流理论,展开电解极板表面拓扑设计,突破复杂气-液多相流场解析与优化瓶颈,全面提升储能过程中物质-能量转化效率,切实降低电解槽运行成本。
招生信息:
本课题组欢迎热爱科学研究与工程应用,具有编程能力,实验动手能力,机械工程,电子工程,光学工程、数学物理等相关理工科背景的本科生和研究生加入课题组。
课题组毕业生信息:
严若鹏:硕士就读期间发表SCI论文5篇,获国家奖学金。毕业去向:武汉大学攻读博士学位。
杨金武:硕士就读期间发表SCI论文3篇。毕业去向:华为技术有限公司。
陈哲:硕士就读期间发表SCI论文2篇。毕业去向:OPPO广东移动通信有限公司。
杨宇轩:硕士就读期间发表SCI论文2篇。毕业去向:迈瑞医疗国际股份有限公司。
杨韵燃:硕士就读期间发表SCI论文2篇。毕业去向:德邦快递。
郑新齐:硕士就读期间发表SCI论文2篇。毕业去向:迈瑞医疗国际股份有限公司。
郑舟:硕士就读期间发表SCI论文2篇。毕业去向:三一重工股份有限公司。
骆迎东:硕士就读期间发表SCI论文6篇,获国家奖学金。毕业去向:获全额奖学金资助,日本东京大学攻读博士学位。
课题信息:
湖北省“BR计划”人才项目(2020-2024),主持
武汉市科技局应用基础前沿项目(2020-2023),主持
湖北省“CT学者”人才项目 (2018-2022),主持
国家自然科学基金委青年项目(2019-2021),主持
武汉市科技局应用基础前沿项目(2018-2020),参与
湖北省青年面上项目(2017-2018),主持
bet36365路检测中心(武汉)摇篮计划(2017-2019),主持
新加坡National Research Foundation: Corp Lab@University Scheme,参与
美国Department of Defense: Concept Award for lung cancer research,参与
新加坡National Research Foundation: Proof-of-Concept project,参与
代表性论文:
X. Duan, Z. Zheng, Y. Luo, T. Dong, Y. Huang, Y. Li, X. Tu and C. Song*, “Development of robust on-demand droplet generation system using 3-D image reconstruction as feedback”, IEEE Transactions on Industrial Electronics, DOI: 10.1109/TIE.2022.3222658 (2022)
X. Duan, B. Xu, X. Zheng, Z. Zheng, Y. Luo, X. Liu, X. Tu and C. Song*, “3-D Visualization of Magnetic Field Using In-Line Holographic Microscopy for Micro-Magnetofluidic Applications”, IEEE Sensors Journal, Vol. 22, 13, 12700-12707 (2022)
Y. Luo, Z. Zheng, X. Zheng, Y. Li, Z. Che, J. Fang, L. Xi, N.-T. Nguyen and C. Song*, “Model-based feedback control for on-demand droplet dispensing system with precise real-time phase imaging”, Sensors and Actuators: B. Chemical, Vol. 365, 131936 (2022)
C. Song, Z. Chen, X. Zheng, S. Yang, X. Duan, Y. Jiang, X. Tu, J. Gan, S. Jiang, “Growth Characteristic Analysis of Haematococcus pluvialis in a Microfluidic Chip Using Digital in-Line Holographic Flow Cytometry”, Analytical Chemistry, Vol. 94(15), 5769-5775 (2022)
X. Tu, J. Wang, Y. Yang, R. Yan, X. Duan and C. Song*, “Chemical reaction monitoring using tunable optofluidic Y-branch waveguides developed with counter-flow”, Microfluidics and Nanofluidics, Vol. 26(4), 1-7 (2022)
A. Sun, T. Li, T. Jin, Y. Li, K. Li, C. Song and L. Xi, “Acoustic Standing Wave Aided Multiparametric Photoacoustic Imaging Flow Cytometry”, Analytical Chemistry, Vol. 93, 44, 14820-14827 (2021)
T. Jin, C., F., X. Chen, G. Liang, F., S. Liang, C. Song, J. Shi, W. Qiu, X. Jiang, K. Li, L. Xi, “On-Chip Multicolor Photoacoustic Imaging Flow Cytometry”, Analytical Chemistry, Vol. 93, 23, 8134-8142 (2021)
X. Zheng, X. Duan, X. Tu, S. Jiang and C. Song*, “The fusion of microfluidics and optics for on-chip detection and characterization of microalgae”, Micromachines, Vol. 12, 10, 1137-1156 (2021)
X. Tu, W. Xie, Z. Chen, M.-F. Ge, T. Huang, C. Song, H.-Y. Fu, “Analysis of Deep Neural Network Models for Inverse Design of Silicon Photonic Grating Coupler”, Journal of Lightwave Technology, Vol. 39, 9, 2790-2799 (2021)
Y. Luo, J. Yang, X. Zheng, J. Wang, X. Tu, Z. Che, J. Fang, L. Xi, N.-T. Nguyen and C. Song*, “Three-dimensional visualization and analysis of flowing droplets in microchannels using real-time quantitative phase microscopy”, Lab on a Chip, Vol. 21, 75-82 (2021) (封底文章)
C. Song, Y. Yang, X. Tu, Z. Chen, J. Gong, C. Lin, “A smartphone-based fluorescence microscope with hydraulically driven optofluidic lens for quantification of glucose”, IEEE Sensors Journal, Vol. 21, No.2, 1229-1235 (2020)
Y. Luo, J. Yang, X. Tu, T. Huang, Z. Che, and C. Song*, “Optofluidic phase-shifting digital holographic microscopy for quantitative measurement of microfluidic diffusion dynamics”, Journal of Applied Physics, Vol. 127, No. 13, 134501 (2020)
R. Yan, J. Yang, Y. Yang, X. Tu, T. Huang, M.F. Ge, Y. Liu and C. Song*, “Cloaking object on an optofluidic chip: its theory and demonstration”, Optics Express, Vol. 28, No.12, 18283-18295 (2020)
X. Zhao, Z. Cheng, M. Zhu, T. Huang*, S. Zeng, J. Pan, C. Song, Y. Wang and P. P. Shum, “Study on the dual-Fano resonance generation and its potential for self-calibrated sensing”, Optics Express, Vol. 28, No. 16, 23703-23716 (2020)
T. Huang, D. Zhang, S. Yoo, Q. Wei, R. Sidharthan, Z. Wu, B. Yan, C. Song, and Z. Cheng, “Reconfigurable multiwavelength fiber laser based on multimode interference in highly germanium doped fiber”, Applied Optics, Vol. 59, No. 4, 1163 (2020)
X. Zhao, T. Huang*, S. Zeng, C. Song, Z. Cheng, X. Wu, P. Huang, J. Pan, Y. Wu, P. P. Shum, “Highly sensitive polarimetric sensor based on Fano resonance for DNA hybridization detection, Plasmonics, (2019).
J. Pan, Z. Chen, T. Huang*, C. Song, P. P. Shum, G. Brambilla, “Fundamental and third harmonic mode coupling induced single soliton generation in Kerr microresonators”, Journal of Lightwave Technology, Vol. 37 (21), 5531-5536 (2019).
R. Yan, Y. Yang, X. Tu, T. Huang, Y. Liu, C. Song*, “Optofluidic light routing via analytically configuring streamlines of microflow”, Microfluidics and Nanofluidics, Vol. 23 (8), 101 (2019)
X. Tu, Y. Luo, T. Huang, J. Gan and C. Song*, “Optofluidic refractive index sensor based on asymmetric diffraction”, Optics Express, Vol. 27 (13), 17809-17818 (2019)
X. Tu, S.L. Chen, C. Song, T. Huang and L.J. Guo, “Ultrahigh Q polymer microring resonators for biosensing applications”, IEEE Photonics Journal, Vol. 11 (2), 1-10 (2019)
X. Tu, C. Song*, T. Huang, Z. Chen, and H. Fu, “State of the art and perspectives on silicon photonic switches”, Micromachines, Vol. 10, 1 (2019)
F. Liu, T. Jin, R. Yan, T. Li, B. Hu, L. Yao, T. Huang, C. Song*, and L. Xi*, “An opto-acousto-fluidic microscopic system with a high spatiotemporal resolution for microfluidic applications”, Optics Express, Vol. 27, 2 (2019)
T. Huang, J. Pan, Z. Cheng, C. Song, J. Wang, X. Shao, P. P. Shum, and G. Brambilla, “Photon-plasmon coupling for fundamental mode phase-matched third harmonic and triplet photon generation”, Journal of Lightwave Technology, Vol. 36, 18 (2018)
W. Guo, A. Teo, A. M. Ganan-Calvo, C. Song, N. T. Nguyen, H. D. Xi, and S. H. Tan, “Pressure-driven filling of closed-end microchannel: realization of comb-shaped transducers for acoustofluidics”, Physical Review Applied, Vol. 10, 5 (2018)
C. Song, Tian Jin, Ruopeng Yan, Weizhi Qi, Tianye Huang, Huafeng Ding, Say Hwa Tan, Nam-Trung Nguyen and Lei Xi, “Opto-acousto-fluidic microscopy for three-dimensional label-free detection of droplets and cells in microchannels”, Lab on a Chip, Vol. 18, 1292-1297 (2018) (封面文章)
C. Song*, N. T. Nguyen and S. H. Tan, “Toward the commercialization of optofluidics”, Microfluidics and Nanofluidics, Vol. 21, 139 (2017)
C. Song* and S. H. Tan, “A perspective on the rise of optofluidics and the future”, Micromachines, Vol. 8, 152 (2017)
H. Guo, C. Song, H. Xie and L. Xi, “Photoacoustic endomicroscopy based on a MEMS scanning mirror”, Optics Letters, Vol. 42, 4615 (2017)
A. Haridas, C. Song, K. Chan and V. M. Murukeshan, “Nondestructive characterization of thermal damages and its interactions in carbon fibre composite panels”, Fatigue & Fracture of Engineering Materials & Structures, Vol. 40 (10), 1562 (2017)
C. Song, Guru Prasad, Kelvin Chan, and Murukeshan V., “Characterization and optimization of illumination translation vector for dimensional parameters measurement of surface form and feature using DSPI”, Review of Scientific Instruments, vol. 87(6), pp. 063116, (2016)
S. R. G. Avila, C. Song, C. D. Ohl, “Fast transient microjets induced by hemispherical cavitation bubbles”, Journal Fluid Mechanics, Vol. 767, pp. 31-51, (2015)
Xi L., C. Song, H. Jiang, "Confocal photoacoustic microscopy using a single multifunctional lens", Optics Letters, Vol. 39, pp. 3328-3331, 2014. (As equally the first author)
C. Song, L. Xi, H. Jiang, "Acoustic lens with variable focal length for photoacoustic microscopy", Journal of Applied Physics, Vol. 114, pp. 194703, (2013)
C. Song, L. Xi, H. Jiang, "Liquid acoustic lens for photoacoustic tomography", Optics Letters, Vol. 38, No. 15, pp. 2930-2933, (2013)
Li H., C. Song, T. D. Luong, N.T. Nguyen, T. N. Wong, "Electrokinetically tunable optofluidic bi-concave lens", Lab on a Chip, Vol. 12, pp. 3680-3687, (2012) (封面文章)
C. Song, N.T. Nguyen, A. Asundi,Cassandra Lee-Ngo Low, “A tunable optofluidic aperture configured by liquid core liquid cladding structure”, Optics Letters, Vol. 36, No. 10, pp. 1767-1769 (2011)
C. Song, T. D. Luong, T. F. Kong, N.T. Nguyen, A.K. Asundi, “Disposable flow cytometer with high efficiency in particle counting and sizing using an optofluidic lens”, Optics Letters, Vol. 36, No. 5, pp. 657-659, (2011)
C. Song, N.T. Nguyen, Y.F. Yap, T.D. Luong, A.K. Asundi, “Multi-functional, optofluidic, in-plane, bi-concave lens: tuning light beam from focused to divergent”, Microfluidics and Nanofluidics, Vol.10, No.3, 671-678 (2010)
C. Song, N.T. Nguyen, A. Asundi, S. H. Tan, “A tuneable micro-optofluidic biconvex lens with mathematically predictable focal length”, Microfluidics and Nanofluidics, Vol. 9, No. 4-5, pp. 889-896, (2010)
C. Song, N.T. Nguyen, A. Asundi, S. H. Tan, “Tunable micro-optofluidic prism based on liquid-core liquid-cladding configuration”, Optics Letters, Vol 35, No. 3, pp. 327-329, (2010)
C. Song, N.T. Nguyen, A. Asundi,Cassandra Lee-Ngo Low, “Biconcave micro optofluidic lens with low-refractive-index liquids”, Optics Letters, Vol. 34, No. 23, pp. 3622-3624, (2009)
C. Song, N.T. Nguyen, S. H., Tan, A. Asundi,“A micro optofluidic lens with short focal length”, Journal of Micromechanics and Microengineering, Vol. 19, No. 8, 085012, (2009)
C. Song, N. T. Nguyen, S. H., Tan and A. Asundi, “Modeling and optimization of micro optofluidic lenses”, Lab on a Chip, Vol. 9, No. 9, pp. 1178–1184, (2009) (封面文章)
C. Song, N. T. Nguyen and A. Asundi, “Optical alignment of a cylindrical object”, Journal of Optics A: Pure and Applied Optics, Vol. 1, No. 3, pp. 034008, (2009)