陶镇生 教授/Professor 密歇根州立大学博士/Ph.D.(2014), Michigan State University, U.S.A. 电话:+86-21-31249067 E-mail:zhenshengtao@fudan.edu.cn zhensheng.tao@outlook.com 主要经历:(Experiences) 2008复旦大学硕士 2014美国密歇根州立大学物理及天文系博士 2014-2018美国JILA,科罗拉多大学博得分校,Kapteyn-Murnane组博士后 2018-至今复旦大学物理系研究员、博士生导师 2018年入选上海市“东方学者”计划 教学与研究领域:(Teaching affairs for foreign faculty) Zhensheng Tao Professor Ph.D.(2014), Michigan State University, U.S.A. Research Interests: Selected Publications: 2)C. Chen, Z. Tao*, et al. Distinguishing attosecond electron–electron scattering and screening in transition metals. PNAS 114, E5300-E5307 (2017). 3) Z. Tao*, C. Chen*, T. Szilvási, M. Keller, M. Mavrikakis, H. Kapteyn, M. Murnane, Direct time-domain observation of attosecond final-state lifetimes in photoemission from solids. Science 353, 62-67 (2016) 4) C. Chen*, Z. Tao*, C. Hernández-García, P. Matyba, A. Carr, R. Knut, O. Kfir, D. Zusin, C. Gentry, P. Grychtol, O. Cohen, L. Plaja, A. Becker, A. Jaron-Becker, H. Kapteyn, M. Murnane, Tomographic reconstruction of circularly polarized high-harmonic fields: 3D attosecond metrology. Science Advances 2, e1501333 (2016). 5) Z. Tao, F. Zhou, T. –R. T. Han, D. Torres, T. Wang, N. Sepulveda, K. Chang, M. Young, R. R. Lunt, C. –Y. Ruan*, The nature of photoinduced phase transition and metastable states in vanadium dioxide. Scientific Reports 6, 38514 (2016). 6) Z. Tao, T. –R. T. Han, S. D. Mahanti, P. M. Duxbury, F. Yuan, C. –Y. Ruan*, K. Wang, J. Wu, Decoupling of Structural and Electronic Phase Transitions in VO2. Physical Review Letters 109, 166406 (2012).
2005复旦大学学士
研究领域与研究兴趣:实验光学、凝聚态物理。主要兴趣在研究光与物质相互作用(特别是强光场条件下)的超快物理过程。我们用实验室尺度强场飞秒激光产生太赫兹、深紫外及软X射线激光,通过光谱学及电子谱学方法研究固体材料的在超快激光激发下的非平衡态动力学过程。研究的时间尺度涵盖阿秒\飞秒尺度的电子及自旋动力学,至皮秒\纳秒尺度的结构动力学。我们的研究目的是为了理解在光与物质相互作用下非平衡态过程的物理本质,探索物质在极端情况下产生新物质态的可能。
Experimental optics and condensed matter physics. Our main research interest lies in the field of ultrafast material dynamics induced by light-matter interaction (especially under the strong-field limit). We generate coherent light covering terahertz to EUV and soft X-ray wavelengths using table-top femtosecond lasers. Through optical and electron spectroscopies, we investigate material dynamics ranging from electron and spin dynamics on attosecond\femtosecond timescales to structural dynamics on picosecond\nanosecond timescales. The purpose of our research is to understand the underlying physics behind the laser-induced non-equilibrium material dynamics and to investigate the exciting opportunities of manipulating material states using optical methods.
1)P. Tengdin, … H. Kapteyn, Z.Tao*, M. Murnane, Critical behavior within 20fs drives the out-of-equilibrium laser-induced magnetic phase transition in nickel. Science Advances in print(2018).