2014年3月27日（周四）下午4點，物理系colloquium：

報告題目： Optical Multi-Dimensional Coherent Spectroscopy 報告人： Steven T. Cundiff, JILA, National Institute of Standards and Technology and University of Colorado 報告時間： 2014-3-27 16:00 報告地點：理科樓鄭裕彤大講堂摘要： The concept of multidimensional Fourier transform spectroscopy originated in NMR where it enabled the determination of molecular structure. In either NMR or optics, a sample is excited by a series of pulses. The key concept is to correlate what happens during multiple time periods between pulses by taking a multidimensional Fourier transform. The presence of a correlation, which is manifest as an off-diagonal peak in the resulting multidimensional spectrum, indicates that the corresponding resonances are coupled. Migrating multidimensional Fourier transform spectroscopy to the infrared and visible regimes is difficult because of the need to obtain full phase information about the emitted signal and for the phase difference between the excitation pulses to be stable and precisely incremented. I will give an introduction to optical two-dimensional coherent spectroscopy, using an atomic vapor as simple test system, but also show unexpected results due to atomic interactions. By extending the method into a 3rd dimension, it is possible to determine the Hamiltonian of an atomic vapor. I will then present our use of it to study optical resonances in semiconductor nanostructures. In quantum wells, our results show that many-body effects dominate the light-matter interaction for excitons in semiconductors and provide a rigorous and quantitative test of the theory. In quantum dots, there is inhomogeneous broadening due to size dispersion, however two-dimensional coherent spectroscopy can make size-resolved measurements without the need to isolate individual quantum dots.
Ref: S.T. Cundiff and S. Mukamel, “Optical Multidimensional Coherent Spectroscopy,” Physics Today 66(7), 44 (July 2013). 個人簡介： Steven T. Cundiff received the B.A. degree in Physics from Rutgers University in 1985. He received M.S. and Ph.D. degrees in Applied Physics from the University of Michigan in 1991 and 1992, respectively. He spent two years as an Alexander von Humboldt Fellow at the University of Marburg, Germany and then joined Bell Laboratories in Holmdel N.J. as a post-doctoral Member of Technical Staff. In 1997 he joined JILA, a joint institute between the University of Colorado and the National Institute of Standards and Technology (NIST), in Boulder, Colorado. He served as Chief of the NIST Quantum Physics Division from 2004 to 2009. Currently, he is a Fellow of JILA, a Physicist with the NIST Quantum Physics Division and a Professor Adjoint in the University of Colorado Department of Physics and Electrical and Computer Engineering Department. He is a Fellow of the Optical Society of America, the American Physical Society and the Institute of Electrical and Electronics Engineers. He received a Humboldt Research Award in 2010 and the Meggers Award from the Optical Society of America in 2011. His current research interests include optical multidimensional Fourier transform spectroscopy, quantum optical spectroscopy of semiconductors, optical arbitrary waveform generation and modelocked laser development.