Ultrafast relaxation time-resolved spectroscopy

It should be stressed that the wave-packet picture of photophysical relaxation and photochemical reaction dynamics described in this chapter is substantially different from the traditional concepts in this area. In contrast to the established picture of radiationless transitions in terms of interacting tiers of zero-order molecular eigenstates, the dynamics is rationalized in terms of local properties of PE surfaces such as slopes, barriers and surface intersections, a view which now becomes widely accepted in photochemistry. This picture is firmly based on ah initio electronic-structure theory, and the molecular relaxation d3mamics is described on the basis of quantum mechanics, replacing previously prevaUing kinetic models of electronic decay processes. Such a more detailed and rigorous description of elementary photochemical processes appears timely in view of the rich and specific information on ultrafast chemical processes which is provided by modern time-resolved spectroscopy. " ... 

Because the high quantum yield originates from the high-rate isomerization, which competes with other relaxation processes in the excited state of rhodopsin, ultrafast laser spectroscopies were applied to investigate the isomerization process of the retinal chromophore. Picosecond time-resolved spectroscopy was appHed to the photochemistry of rhodopsin, and the formation of the primary intermediates was reported, such as photorhodopsin and bathorhodopsin at room temperature. - - However, the time resolution needed to be improved in order to detect the cis-tram isomerization process in the excited state of rhodopsin. The direct observation of the rhodopsin excited state was reported in 1991, in which the primary intermediate photorhodopsin formed from the excited state of rhodopsin within 200 fs. Later, the effects of oscillatory features with a period of 550 fs (60 cm ) on the formation kinetics of photorhodopsin, were observed, suggesting that the primary step in vision is a vibrationally coherent process. 

Hudock et al. [126] used the ab initio molecular dynamics multiple spawning method to go beyond the static picture based on PES and include the time dependent dynamical behavior and predict time-resolved photoelectron spectroscopy results. According to these results the first ultrafast component of the photoelectron spectra of uracil corresponds to relaxation on the S2 minimum rather than nonadiabatic transitions to the Si state. The authors suggest that the radiationless relaxation from... 

Time resolved coherent anti-Stokes Raman spectroscopy of condensed matter has been recently extended to the femtosecond domain allowing direct and detailed studies of the fast relaxation processes of molecular vibrations in liquids. The vibrational phase relaxation (dephasing) is a fundamental physical process of molecular dynamics and has attracted considerable attention. Both experimental and theoretical studies have been performed to understand microscopic processes of vibrational dephasing. Developments in ultrafast coherent spectroscopy enables one now to obtain direct time-domain information on molecular vibrational dynamics. Femtosecond time-resolved coherent anti-Stokes Raman scattering measuring systems have been constructed (see Sec. 3.6.2.2.3) with an overall time resolution of less than 100 fs (10 s). Pioneering work has been per-... 

The vibronic spectra of Do — Di — D2 electronic states recoded by da Silva Filho et al. [45] revealed resolved vibrational structures of the Do and D2 electronic states and a broad and structureless band for the Di state. A slow ( 3-20 ps) and fast k, 200 fs) relaxation components are estimated for the Dq D2 transition in a (femto)picosecond transient grating spectroscopy measurements [16]. The fast component is attributed to the Do D2 transition and a nonradiative relaxation time of 212 fs is also estimated from the cavity ringdown (CRD) spectroscopy data [42]. Electronic structure results of Hall et al. [107] suggest that the nonradiative Do D2 relaxation occurs via two consecutive sloped type CIs [66,108]. We developed a global model PESs for the Do — Di— D2 electronic states and devised a vibronic coupling model to study the nuclear dynamics underlying the complex vibronic spectrum and ultrafast excited state decay of N +[20]. 

Picosecond time-resolved Raman spectroscopy has been used to study the ultrafast relaxation dynamics of trows-stilbene cation radicals following two-photon ionization in acetonitrile [66]. The integrated Raman intensities due to the cation radicals rise in... 

Acylazides. Ultrafast IR and UV studies of acylazides and sulphonylazide have been published. The photochemistry of aliphatic and aromatic acylazides has been studied by femtosecond time-resolved IR and UV-visible spectroscopy. Despite the fact that the excited state is either %% or nri in the azides studied the signals were similar. A hot nitrene was produced more efficiently from both the higher singlet excited states and hot than from relaxed... 

Optoelectronic detection systems such as fast photodiodes and sampling oscilloscopes have reached a time resolution of lO" s. However, this is still not sufficient to resolve many fast transient events on a picosecond time scale. In picosecond spectroscopy, therefore, new techniques had to be invented to measure durations and profiles of picosecond pulses and to probe ultrafast relaxation processes. 

In this chapter we describe advances in the femtosecond time-resolved multiphoton photoemission spectroscopy (TR-MPP) as a method for probing electronic structure and ultrafast interfacial charge transfer dynamics of adsorbate-covered solid surfaces. The focus is on surface science-based approaches that combine ultrafast optical pump probe excitation to induce nonlinear multi-photon photoemission (MPP) from clean or adsorbate covered single crystal surfaces. The photoemitted electrons transmit spectroscopic and dynamical information, which is captured by their energy analysis in real or reciprocal space. We examine how photoelectron spectroscopy and microscopy yield information on the unoccupied molecular structure, electron transfer and relaxation processes, light induced chemical and physical transformations and the evolution of coherent single particle and collective excitations at solid surfaces. 

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