季敏标 美国斯坦福大学博士 电话:+86-21-31247899 E-mail:Minbiaoj@fudan.edu.cn 个人网站/Website:链接/Link 主要经历:(Experiences) 2011美国斯坦福大学物理系博士 2011-2014哈佛大学化学与生物化学博士后 2014-至今复旦大学物理系研究员、教授 教学与研究领域: 1.利用超快光谱技术研究材料中载流子的非平衡态动力学以及手性分子的表征。 2.利用相干拉曼成像技术研究生物和生物医学问题,包括肿瘤的非标记探测和脂类代谢等问题。 3.利用非线性光学成像手段来表征材料和器件。 Minbiao Ji Professor Ph.D.(2011), Stanford University, U.S.A. Research Interests: Selected Publications: 2)Kong L.,* M. Ji,* Gary R. Holtom, X. Sunney Xie, et al. “Multi-color stimulated Raman scattering microscopy with a rapidly tunable optical parametric oscillator.” Optics Letters 38(2): 145-147. (2012) 3) Jhaa, S. K.,* M. Ji,* K. J. Gaffney, S. G. Boxer. Direct measurement of the protein response to an electrostatic perturbation that mimics the catalytic cycle in ketosteroid isomerase. Proceedings of the National Academy of Sciences U. S. A.108(40): 16612-16617. (2011) 4) Ji, M. and K. J. Gaffney. Orientational relaxation dynamics in aqueous ionic solution: Polarization-selective two-dimensional infrared study of angular jump-exchange dynamics in aqueous 6M NaClO4. Journal of Chemical Physics 134(4): 044516. (2011) 5) Ji, M., M. Odelius, K. J. Gaffney. Large Angular Jump Mechanism Observed for Hydrogen Bond Exchange in Aqueous Perchlorate Solution. Science 328(5981): 1003-1005. (2010) 6) Ji, M., S. Park, K. J. Gaffney. Dynamics of Ion Assembly in Solution: 2DIR Spectroscopy Study of LiNCS in Benzonitrile. Journal of Physical Chemistry Letters 1(12): 1771-1775. (2010) 7) Ji, M., S. Park, Yi Cui, K. J. Gaffney, et al. Efficient Multiple Exciton Generation Observed in Colloidal PbSe Quantum Dots with Temporally and Spectrally Resolved Intraband Excitation. Nano Letters 9(3): 1217-1222. (2009) 8) Lai, K., M. B. Ji, Z. X. Shen, et al. Atomic-force-microscope-compatible near-field scanning microwave microscope with separated excitation and sensing probes. Review of Scientific Instruments 78(6): 063702. (2007)
2005北京大学物理系学士
非线性光谱学和非线性光学显微成像技术。
Nonlinear optical spectroscopy and microscopy. We utilize ultrafast spectroscopic techniques to study carrier dynamics in novel materials as well as characterize chiral molecules. We are also interested in using coherent Raman scattering microscopy to study various biological and biomedical problems, such as label-free delineation of tumor and lipid metabolism. Novel nonlinear optical imaging techniques can also be used to learn the physics in material and devices.
1)Ji, M.,* D. A. Orringer,* C. W. Freudiger, X. Sunney Xie, et al. Rapid, label-free detection of brain tumors with stimulated Raman scattering microscopy. Science Translational Medicine, 5, 201ra119. (2013, cover story)