Chemical Reactions in Solution: The New Photochemistry

Laser Chemistry Pub Date : 1900-01-01 DOI:10.1155/LC.3.163

G. Robinson, W. Jalenak

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引用次数: 2

Abstract

Understanding the dynamics of chemical reactions in the condensed phase reaches a new plateau with each technological advance in time-resolved spectroscopy. Submicrosecond studies of the past revealed the role of long range molecular diffusion in condensed-phase chemistry and photochemistry. The picosecond (10−12–10−9 s) time scale, combined with the use of a high concentration of reactants, can provide new information about the “microdynamics” in the local region of the reaction itself. The role of solvent is particularly important: how it attaches to an activated reactant molecule, how it is displaced by the other reactant molecule preparatory to reaction, and how the solvent behavior affects the dynamics of single- and multi-channel processes, thus the relative yields of products in competing reactions. The theory presented here divides itself into two types: one that depends on a diffusion equation that also contains terms describing a distance-dependent reaction sink function and a reaction barrier; and a second type that deals phenomenologically with rate equations, including the rate of reactant/solvent interchange. Experiments subdivide naturally into steady state and transient measurements, the former dealing with quantum yields and steady state spectroscopic studies, the latter with picosecond transient spectroscopy. The two theoretical approaches can be interrelated in certain useful limits. The two types of experimental data, in combination with the theory, supply fundamental information about solvent participation in the local reaction region.

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溶液中的化学反应:新的光化学

随着时间分辨光谱技术的每一次进步，对凝聚态化学反应动力学的理解达到了一个新的平台。过去的亚微秒研究揭示了远程分子扩散在凝聚相化学和光化学中的作用。皮秒(10−12-10−9 s)时间尺度，结合高浓度反应物的使用，可以提供有关反应本身局部区域“微动力学”的新信息。溶剂的作用尤为重要:它如何附着在活化的反应物分子上，它如何被准备反应的其他反应物分子取代，溶剂的行为如何影响单通道和多通道过程的动力学，从而影响竞争反应中产物的相对产率。这里提出的理论分为两种类型:一种依赖于扩散方程，扩散方程也包含描述距离依赖的反应汇函数和反应势垒的术语;第二种是从现象学上研究速率方程，包括反应物/溶剂交换速率。实验自然又分为稳态测量和瞬态测量，前者涉及量子产率和稳态光谱研究，后者涉及皮秒瞬态光谱。这两种理论方法在某些有用的限度内可以相互联系。这两种类型的实验数据与理论相结合，提供了溶剂参与局部反应区域的基本信息。

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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Laser Chemistry

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