以下按英文字母顺序排列:
姓  名:  方晖
性  别:  
所属部门:  现代光学研究所
行政职务:  
职  称:  教授
学  历:  博士
所学专业:  光学成像
办公电话:  022-23503195
电子邮件:  fanghui@nankai.edu.cn
研究方向:  光谱成像,光声探测技术
个人简介:  Introduction - Hui Fang, Professor of Nankai University, College of Information Technical Science, Institute of Modern Optics. Ph.D. in Physics, Boston University, 2005. Postdoctoral Fellow, Harvard Medical School, Beth Israel Deaconess Medical Center, 2005-2006. Postdoctoral Associate, Washington University in St. Louis, the Department of Biomedical Engineering, 2007-2008. Expertise and Interests: Optical Microscopy and Spectroscopy, Photoacoustic Flow Sensing and Imaging. Representative Research Works: CLASS Microscopy, Photoacoustic Doppler Effect.
 
 湖南岳阳人,1973年生。分别于1994年和1997年在中国科学技术大学物理系获学士和光学硕士,于2000年在南开大学现代光学研究所获光学工程学博士,于2005年在美国波士顿大学物理系获物理学博士。随后在哈佛大学医学院和圣路易斯华盛顿大学生物医学工程系从事博士后研究,于2008年回南开大学任职。
 
  曾经所涉及的研究领域包括近场光学衍射计算、数字化图像白光信息处理、共聚焦颗粒散射光谱显微成像、基于颗粒光声效应的流速测量等。在这些研究方面作为主要作者曾在包括Proceedings of National Academy of Sciences(PNAS)、Physical Review Letters、Applied Physics Letters、Optics Letters、IEEE J. Selected Topics in Quantum Electronics、Applied Optics等期刊发表科研论文。并已为国外的期刊Optics Express, Optics Letters, Applied Optics, J. Biomedical Optics, IEEE Trans. on Instrumentation and Measurement ,以及国内的期刊Chinese Physics B, Chinese Optics Letters, 物理学报、光学精密工程、计算物理审稿。
 
  目前的研究课题以微纳米颗粒的光学特性而展开,主要集中在三个方向:一是基于颗粒光散射特性的超高分辨率光谱成像技术,二是基于颗粒光吸收特性的光声液体流速探测技术,三是基于金属纳米颗粒的表面增强拉曼光谱成像技术。第一个方向的工作基础是与哈佛大学医学院Lev Perelman教授小组的同事共同发展的“共聚焦光吸收及散射光谱的显微成像技术”(见论文[20]、[6]),第二个方向的工作基础是与圣路易斯华盛顿大学Lihong Wang教授小组的同事共同实验发现的“光声多普勒效应”(见论文[22]、[21],以及http://en.wikipedia.org/wiki/Photoacoustic_Doppler_effect)。第三个方向是在与袁小聪教授小组合作的基础上进行,主要集中于将新型轴向矢量光束与拉曼表面增强光谱研究相结合。针对这些方向,在深入进行机理研究及发展相关技术的同时,还将积极寻求这些技术在成像光学、微纳光学、生物医学光学,以及流体力学中的实际应用。
 
 非常欢迎对这些研究课题感兴趣的同学询问报考硕士或博士研究生事宜。(关于其他情况可查看现代光学所的网页:http://it.nankai.edu.cn/imo/index.aspx)
 
科研项目、成果、获奖、专利等情况:  科研项目:
 2014.4-2017.3,天津市应用基础与前沿技术研究计划(14JCYBJC16600),10.0万元
 2014.1-2016.12,教育部博士点基金博导类(20130031110036),12.0万元
 2012.1-2014.12,教育部留学回国人员科研启动基金(42批[2011]1139号),3.0万元
 2011.1-2013.12,国家自然科学基金(11074134),37.0万元 (已结题)
 2010.1-2012.12, 教育部博士点基金新教师类(20090031120043),3.6万元 (已结题)
 
 2012.1-2016.12,国家自然科学基金重点项目(61138003),参加
 2010.4-2013.3,天津市应用基础与前沿技术研究计划 (10JCYBJC11500),参加(已结题)
 
 奖励:
 入选教育部2010年度新世纪优秀人才支持计划 (NCET-10-0502)
 
 专利:
 [1] L. V. Wang, H. Fang, and K. Maslov, Photoacoustic Doppler Flow Sensing and Imaging, US Patent (2011/7,917,312).
撰写论文、专著、教材等:  期刊论文:
 [27] Y. Li, and H. Fang*, "Photoacoustic pulse wave forming along the rotation axis of an ellipsoid droplet: a geometric calculation study," Applied Optics, vol. 52, pp. 8258-8269, 2013.
 [26] J. F. Shen, J. Wang, C. J. Zhang, C. J. Min, H. Fang*, L. P. Du, S. W. Zhu, and X. C. Yuan*, "Dynamic plasmonic tweezers enabled single-particle-film-systerm gap-mode surface-enhanced Raman scattering," Applied Physics Letters, vol.103: 191119, 2013.
 [25] R. Y. Yin, Y. Tong, Y. Q. Zhao, and H. Fang*, "Optical Doppler technologies for microcirculation measurement and their recent progress," 光学技术, vol. 39, pp. 112-123, 2013.
 
 [24] H. Fang, and A. P. Yang, "Acquisition of elastic backscattering spectra for microsphere sizing beyond diffraction limit," 光学精密工程, vol. 22, pp. 547-554, 2014.
 [23] H. Fang, and L. V. Wang, “M-mode photoacoustic particle flow imaging,”Optics Letters, vol.34, pp.671-673, 2009.
 [22] H. Fang, K. Maslov, and L. V. Wang, “Photoacoustic Doppler flow measurement in optically scattering media,” Applied Physics Letters, vol. 91, pp. 264103(1-3), 2007.
 [21] H. Fang, K. Maslov, and L. V. Wang, “Photoacoustic Doppler effect from flowing small light-absorbing particles,” Physical Review Letters, vol. 99, pp. 184501(1-4), 2007.
 [20] H. Fang, L. Qiu, E. vitkin, M. M. Zaman, C. Andersson, S. Salahuddin, L. M. Kimerer, P. B. Cipolloni, M. D. Modell, B. S. Turner, S. E. Keates, I. Bigio, I. Itzkan, S. D. Freedman, R. Bansil, E. B. Hanlon, and L. T. Perelman, “Confocal light absorption and scattering spectroscopic microscopy,” Applied Optics, vol. 46, pp. 1760-1769, 2007.
 [19] H. Fang, M. Ollero, E. Vitkin, L. M. Kimerer, P. B. Cipolloni, M. M. Zaman, S. D. Freedman, I. J. Bigio, I. Itzkan, E. B. Hanlon, and L. T. Perelman, “Noninvasive sizing of subcellular organelles with light scattering spectroscopy,” IEEE J. Selected Topics in Quantum Electronics, vol. 9, pp. 267-276, 2003.
 [18] H. Fang, G. Luo, P. Zhao, Z. L. Fang, and G. G. Mu, “The study of a new format color filter used for a digital camera,” 仪器仪表学报, vol. 22, pp. 277-282, 2001.
 [17] H. Fang, G. Luo, Z. L. Fang, and G. G. Mu, “Deviation inspecting of DIP chip pin location based on Harr wavelet transformation,” 仪器仪表学报, vol. 21, pp.604-607, 2000.
 [16] H. Fang, G. Luo, Z. L. Fang, and G. G. Mu, “Experimental study of a new color filter used for a digital camera,” 光电子激光, vol. 11, pp. 579-582, 2000.
 
 [15] Y. Li, and H. Fang, "A geometric calculation method for photoacoustic wave profile on symmetry axis of an ellipsoid particle," 计算物理, vol. 30, pp.124-129, 2013.
 [14] C. J. Min, Z. Shen, J. F. Shen, Y. Q. Zhang, H. Fang, G. H. Yuan, L. P. Du, S. W. Zhu, T. Lei, and X. C. Yuan, "Focused plasmonic trapping of metallic partices," Nature Communications, vol.4: 2891, 2013.
 [13] L. P. Du, D. Y. Lei, G. H. Yuan, H. Fang, X. Zhang, Q. Wang, D. Y. Tang, C. J. Min, S. A. Maier, and X. C. Yuan,"Mapping plasmonic near-field profiles and interferences by surface-enhanced Raman scattering," Scientific Reports, vol. 3: 3064, 2013.
 [12] P. Jia, Y. Yang, C. J. Min, H. Fang, and X. C. Yuan, "Sidelobe-modulated optical vortices for free-space communication," Optics Letters, vol. 38, pp. 588-590, 2013.
 [11] Z. Shen, Z. J. Hu, G. H. Yuan, C. J. Min, H. Fang, and X. C. Yuan, "Visualizing orbital angular momentum of plasmonic vortices," Optics Letters, vol. 37, pp. 4627-4629, 2012.
 [10] H. Bai, P. Chen, G. Q. Tang, L. Lin, H. Fang, G. G. Mu, W. Gong, Z. P. Liu, Z. B. Han, H. Zhao, and Z. C. Han, "Relations between reactive oxygen species and Raman spectral variations of human umbilical cord mesenchymal stem cells with different viability," Laser Physics, vol. 21, pp. 1122-1229, 2011.
 [9] J. J. Bai, J. N. Li, H. Zhang, H. Fang, and S. J. Chang, "A porous terahertz fiber with randomly distributed air holes," Applied Physics B: Laser and Optics, vol. 103, pp. 381-386, 2011.
 [8] H. Bai, P. Chen, H. Fang, L. Lin, G. Q. Tang, G. G. Mu, W. Gong, Z. P. Liu, H. Wu, H. Zhao, and Z. C. Han, "Detecting viability transitions of umbilical cord mesenchymal stem cells by Raman micro-spectroscopy," Laser Physics Letters, vol. 8, pp. 78-84, 2011.
 [7] K. Lim, S. Salahuddin, L. Qiu, H. Fang, E. Vitkin, I. C. Ghiran, M. D. Modell, T. Takooudes, I. Itzkan, E. B. Hanlon, B. P. Sachs, and L. T. Perelman, “Light-scattering spectroscopy differentiates fetal from adult nucleated red blood cells: may lead to noninvasive prenatal diagnosis,”Optics Letters, vol.34, pp. 1483-1485, 2009.
 [6] I. Itzkan, L. Qiu, H. Fang, M. M. Zaman, E. Vitkin, I. C. Ghiran, S. Salahuddin, M. Modell, C. Andersson, L. M. Kimerer, Cipolloni, Kee-Hak Lim, S. D. Freedman, I. Bigio, B. P. Sachs, E. B. Hanlon, and L. T. Perelman, “Confocal light absorption and scattering spectroscopic microscopy monitors organelles in live cells with no exogenous labels,” Proceedings of National Academy of Sciences(PNAS), vol. 104, pp. 17255-17260, 2007.
 [5] G. Luo, O. Chutatape, and H. Fang, “Experimental study on nonuniformity of line jitter in CCD images,” Applied Optics, vol. 40, pp. 4716-4720, 2001.
 [4] G. Luo, H. Fang, Z. L. Fang, and G. G. Mu, “Experimental studies on phase drift of digital images,” 仪器仪表学报, vol. 22, pp.65-71, 2001.
 [3] G. Luo, H. Fang, Z. L. Fang, and G. G. Mu, “ Method for the deviation inspection of integrated circuit chip pin based on Harr wavelet transform,” Optical Engineering, vol. 39, pp. 1712-1716, 2000.
 [2] J. P. Xie, W. M. Wu, H. Fang, X. H. Sun, Y. X. Wu, and H. Ming, “Boundary diffraction method for aperture near-field diffraction,” Chinese Physics Letters, vol. 16, pp. 811-813, 1999.
 [1] J. P. Xie, H. Fang, S. T. Wang, W. M. Wu, G. Wang, Y. X. Wu, W. Gao, G. P. Zhang, and H. Ming, “Approach of near field diffraction pattern by the sampling theorem,” 光学学报, vol. 19, pp. 785-790, 1999.
 
 会议论文:
 [4] H. Fang, K. Maslov, and L. V. Wang, “M-mode photoacoustic flow imaging,” Proceedings of the SPIE (Photonics West Symposium: Photons Plus Ultrasound: Imaging and Sensing), vol. 7177, 71772M-(1-8), 2009.
 [3] H. Fang and L. V. Wang, “Photoacoustic Doppler Flowmetry,” Proceedings of the SPIE (Photonics West Symposium: Photons Plus Ultrasound: Imaging and Sensing), vol. 6856, 68561M-(1-8), 2008.
 [2] H. Fang, L. Qiu, S. Salahuddin, E. Vitkin, M. D. Modell, E. B. Hanlon, I. Itzkan, and L. T. Perelman, “Confocal light scattering spectroscopic microscopy for monitoring individual subcellular organelles,” in Biomedical Topical Meeting, OSA Technical Digest (The Optical Society of America, Washington, DC, 2006), TuH2.
 [1] H. Fang, E. Vitkin, M. Ollero, I. Itzkan, E. B. Hanlon, and L. T. Perelman, “Light scattering spectroscopy for measuring subcellular organelles,” in Biomedical Topical Meeting, OSA Technique Digest (The Optical Society of America, Washington, DC, 2004), FF3.
 
 专著:
 [1] H. Fang and L. V. Wang, “Photoacoustic Doppler effect and flow sensing,” in 《Photoacoustic imaging and spectroscopy 》, ed. L. V. Wang (Taylor & Francis Group, 2009).
讲授课程:  《光谱学》(硕士生课程),《英语科技写作》(博士生课程)
社会兼职:  OSA会员,SPIE会员,中国光学学会会员,《应用物理》期刊编委