由脉冲X射线拉曼过程触发的分子中的非线性光散射。
Nonlinear light scattering in molecules triggered by an impulsive X-ray Raman process.
作者信息
Dorfman Konstantin E, Bennett Kochise, Zhang Yu, Mukamel Shaul
机构信息
University of California, Irvine, California 92697-2025.
出版信息
Phys Rev A. 2013 May 1;87(5):53826. doi: 10.1103/PhysRevA.87.053826.
Abstract
The time-and-frequency resolved nonlinear light scattering (NLS) signals from a time evolving charge distribution of valence electrons prepared by impulsive X-ray pulses are calculated using a superoperator Green's function formalism. The signal consists of a coherent ~ -scaling difference frequency generation and an incoherent fluorescence ~ -scaling component where is the number of active molecules. The former is given by the classical Larmor formula based on the time-dependent charge density. The latter requires additional information about the electronic structure and may be recast in terms of transition amplitudes representing quantum matter pathways.
摘要
利用超算符格林函数形式,计算了由脉冲X射线脉冲制备的价电子随时间演化的电荷分布产生的时间和频率分辨非线性光散射(NLS)信号。该信号由相干的~ -标度差频产生和非相干荧光~ -标度分量组成,其中是活性分子的数量。前者由基于随时间变化的电荷密度的经典拉莫尔公式给出。后者需要关于电子结构的额外信息,并且可以根据代表量子物质路径的跃迁振幅进行重新表述。
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