Ultrafast nano-imaging resolving structure, coupling, and dynamics of matter on its natural length and time scales
活动时间:
2022年9月28日(周三)19:00
报告嘉宾:
Prof. Markus Raschke
主办单位:
蔻享学术
直播通道
蔻享学术直播间
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报告人介绍
Prof. Markus Raschke
Markus Raschke is a professor at the Department of Physics, Department of Chemistry, and JILA at the University of Colorado at Boulder. The research in his group is on the development of new nano-scale nonlinear and ultrafast spectroscopy techniques to control the light-matter interaction on the nanoscale and image domain order correlated matter. He received his PhD in 2000 from the Max-Planck Institute of Quantum Optics and the Technical University in Munich, Germany. Following research appointments at the University of California at Berkeley, and the Max-Born-Institute in Berlin, he became faculty member at the University of Washington, before moving with his group to Boulder in 2010. Prof. Markus Raschke published more than 100 peer-reviewed articles (among others in Science and Nature) focused on experimental nonlinear and ultrafast nano-optics. Spatio-temporal optical control, optical antennas, surface plasmon and phonon polaritons, extreme nonlinear optics, strong light matter interaction.AWARDs AND HONORS- 2018 Distinguished Visiting Professor, Tongji University, Shanghai- 2015 Klaus Halbach Award, Lawrence Berkeley National Laboratory- 2012 Visiting Professor, Abbe School of Photonics, Jena- 2008 National Science Foundation CAREER Award- 1999 Otto-Hahn-Medal of the Max-Planck-Society, Award
报告简介
In this webinar, I will discuss our recent progress in the area of nanoscale light manipulation and imaging using strongly coupled light-matter oscillations in van der Waals materials and engineered materials made of these constituents. I discuss the opportunities to control and tailor photons at the nanoscale as they interact with phonon resonances in the mid-infrared range or exciton resonances in the visible. During the presentation, I will discuss the unusual phenomena supported by these structures, and their opportunities for nano-imaging and information transport.