Use of liquid-core waveguides as photochemical reactors and/or for chemical analysis – An overview

IF 3.261
Iris Groeneveld , Amber Jaspars , Imran B. Akca , Govert W. Somsen , Freek Ariese , Maarten R. van Bommel
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引用次数: 1

Abstract

The study of photochemical reactions is of great importance in many fields including the pharmaceutical, food, and paint industry. Most of these photochemical processes are being studied to better understand how to apply them for a specific purpose or how unwanted effects can be prevented. Advances are still being made in photoreactor design, where in-situ detection of the involved reagents and products is an important development. Liquid-core waveguides (LCWs) allow simultaneous illumination and optical assessment of liquid samples and, therefore, constitute one way of combining photoreactor design with on-line or in-situ analytical detection methods. LCWs possess several interesting characteristics, such as low light loss, increased optical path length, and possibilities for coupling with spectroscopic techniques. The current review discusses the state-of-the-art of LCWs applied as photoreactors, for analytical detection, and their combinations. We discuss the differences between several total internal reflection (TIR)-based LCWs, including polymer and polymer-coated capillaries, and silica aerogels, and interference-based waveguides, including Bragg fibers, holey fibers, Kagomé fibers and anti-resonance reflecting optical waveguides (ARROWs). Assessed characteristics include the (freedom of) design, the degree of light attenuation, the range of transmittable wavelengths, gas permeability, compatibility with analytical techniques, current challenges, and applications.

液芯波导作为光化学反应器和/或化学分析的应用。概述
光化学反应的研究在包括制药、食品和油漆工业在内的许多领域都具有重要意义。人们正在研究这些光化学过程中的大多数,以更好地了解如何将它们应用于特定目的或如何防止不必要的影响。在光反应器设计方面仍在取得进展,其中所涉及的试剂和产物的原位检测是一个重要的发展。液芯波导(LCWs)允许同时对液体样品进行照明和光学评估,因此构成了将光反应器设计与在线或原位分析检测方法相结合的一种方法。LCWs具有几个有趣的特性,如低光损耗,增加光程长度,以及与光谱技术耦合的可能性。本文讨论了LCWs用作光反应器、分析检测及其组合的最新进展。我们讨论了几种基于全内反射(TIR)的光波导,包括聚合物和聚合物涂层的毛细血管,以及二氧化硅气凝胶,以及基于干涉的波导,包括Bragg光纤,多孔光纤,kagom光纤和抗共振反射光波导(箭头)之间的差异。评估的特征包括(自由度)设计、光衰减程度、可透射波长范围、气体渗透性、与分析技术的兼容性、当前挑战和应用。
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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来源期刊
CiteScore
4.10
自引率
0.00%
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