Time-resolved Photoelectron Imaging Using Ultrashort VUV Pulses

T. Horio
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Abstract

A photoexcited molecule is deactivated through a variety of photo-physical/chemical processes, and ultimately relaxes to the ground electronic state (S0) or further undergoes chemical reactions in S0. Time-resolved photoelectron imaging (TRPEI) [1] enables full observation of these photoinduced dynamics, because photoionization can be induced from any part of the potential energy surfaces (PESs). However, observation of low-lying electronic excited states and S0 requires probe pulses in the vacuum ultraviolet (VUV) region, and it has been difficult to generate intense ultrashort VUV laser pulses. Following the generation of sub-20 fs deep UV (DUV) pulses at 4.7 and 6.3 eV by cascaded filamentation four-wave mixing (FWM) [2], we have succeeded in generating ultrashort DUV and VUV (7.8 and 9.3 eV) pulses simultaneously [3,4]. While this light source is simple and easily implemented (Fig. 1), it provides multiple colors with ultrashort time-duration (<20 fs) without any dispersion control (Fig. 2). Thus, it is an ideal light for TRPEI. In this talk, we present TRPEI using ultrashort VUV pulses to obtain a “global reaction map” of photoinduced dynamics of an isolated molecule.
利用超短VUV脉冲进行时间分辨光电子成像
光激发分子通过各种光物理/化学过程失活,最终松弛到基电子态(S0)或进一步在S0中发生化学反应。时间分辨光电子成像(TRPEI)[1]可以充分观察这些光致动力学,因为光电离可以从势能表面(PESs)的任何部分诱导。然而,观测低洼电子激发态和S0需要在真空紫外(VUV)区探测脉冲,并且很难产生强超短的VUV激光脉冲。继通过级联丝化四波混频(FWM)产生4.7和6.3 eV的20秒以下深紫外(DUV)脉冲后[2],我们成功地同时产生了7.8和9.3 eV的超短DUV和VUV脉冲[3,4]。虽然该光源简单且易于实现(图1),但它可以提供超短持续时间(<20 fs)的多种颜色,而无需任何色散控制(图2)。因此,它是TRPEI的理想光源。在这次演讲中,我们介绍了使用超短紫外脉冲的TRPEI来获得一个孤立分子的光诱导动力学的“全局反应图”。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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