获取具有极端氧化还原电位的光敏剂的策略

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Dooyoung Kim, Thomas S. Teets
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引用次数: 10

摘要

光氧化还原催化在许多应用中都很突出,包括太阳能燃料、有机合成和聚合物化学。光催化活性直接取决于光催化剂在基态和激发态下的光物理和电化学性质。因此,控制这些性质对于实现所需的光催化活性是必不可少的。氧化还原电位是影响光氧化还原催化中关键基本步骤的热力学和动力学方面的一个重要因素。在有机合成中的许多具有挑战性的反应中,底物的高氧化还原电位阻碍了反应,导致转化缓慢。因此,需要开发具有极端氧化还原电位并伴有强大还原或氧化能力的光催化剂,以执行高产率的热力学要求反应。在这篇综述中,我们将介绍在光催化转化中获得极端氧化还原电位的策略。其中包括制备光敏剂的分子设计策略,这些光敏剂是异常强的基态或激发态还原剂或氧化剂,突出了有机和金属基光敏剂。我们还概述了获得极端氧化还原电位的方法,使用双光子激活或电化学/光化学组合策略,从具有较温和电位的前体中产生强效氧化还原试剂。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Strategies for accessing photosensitizers with extreme redox potentials
Photoredox catalysis has been prominent in many applications, including solar fuels, organic synthesis, and polymer chemistry. Photocatalytic activity directly depends on the photophysical and electrochemical properties of photocatalysts in both the ground state and excited state. Controlling those properties, therefore, is imperative to achieve the desired photocatalytic activity. Redox potential is one important factor that impacts both the thermodynamic and kinetic aspects of key elementary steps in photoredox catalysis. In many challenging reactions in organic synthesis, high redox potentials of the substrates hamper the reaction, leading to slow conversion. Thus, the development of photocatalysts with extreme redox potentials, accompanied by potent reducing or oxidizing power, is required to execute high-yielding thermodynamically demanding reactions. In this review, we will introduce strategies for accessing extreme redox potentials in photocatalytic transformations. These include molecular design strategies for preparing photosensitizers that are exceptionally strong ground-state or excited-state reductants or oxidants, highlighting both organic and metal-based photosensitizers. We also outline methodological approaches for accessing extreme redox potentials, using two-photon activation, or combined electrochemical/photochemical strategies to generate potent redox reagents from precursors that have milder potentials.
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