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布朗斯特酸和路易斯酸加合物与富电子杂环芳烃的形成及反应

Formation and Reactions of Brønsted and Lewis Acid Adducts with Electron-Rich Heteroaromatic Compounds.

作者信息

Hartmann Horst, Liebscher Jürgen

机构信息

Fakultät Chemie und Lebensmittelchemie, Technische Universität Dresden, 01069 Dresden, Germany.

National Institute for Research and Development of Isotopic and Molecular Technologies INCDTIM, 400293 Cluj-Napoca, Romania.

出版信息

Molecules. 2024 Jul 2;29(13):3151. doi: 10.3390/molecules29133151.

DOI:10.3390/molecules29133151
PMID:38999101
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11243428/
Abstract

Electron-rich heteroaromatics, such as furan, thiophene and pyrrole, as well as their benzo-condensed derivatives, are of great interest as components of natural products and as starting substances for various products including high-tech materials. Although their reactions with Brønsted and Lewis acids play important roles, in particular as the primary step of various transformations, they are often disregarded and mechanistically not understood. The present publication gives a first overview about this chemistry focusing on the parent compounds. It comprises reactions with strong Brønsted acids forming adducts that can undergo intramolecular proton and/or substituent transfer reactions, ring openings or ring transformations into other heterocycles, depending on their structure. Interactions with weak Brønsted acids usually initiate oligomerizations/polymerizations. A similar behaviour is observed in reactions of these heteroaromatics with Lewis acids. Special effects are achieved when the Lewis acids are activated through primary protonation. Deuterated Brønsted acids allow straight forward deuteration of electron-rich heteroaromatics. Mercury salts as extremely weak Lewis acids cause direct metalation in a straight forward way replacing ring H-atoms yielding organomercury heterocycles. This review will provide comprehensive information about the chemistry of adducts of such heterocycles with Brønsted and Lewis acids enabling chemists to understand the mechanisms and the potential of this field and to apply the findings in future syntheses.

摘要

富电子杂芳烃,如呋喃、噻吩和吡咯,以及它们的苯并稠合衍生物,作为天然产物的组成部分和包括高科技材料在内的各种产品的起始物质,备受关注。尽管它们与布朗斯特酸和路易斯酸的反应起着重要作用,特别是作为各种转化的第一步,但这些反应常常被忽视,其反应机理也未得到理解。本出版物首次对这类化学进行了综述,重点关注母体化合物。它包括与强布朗斯特酸形成加合物的反应,这些加合物可根据其结构进行分子内质子和/或取代基转移反应、开环或环转化为其他杂环。与弱布朗斯特酸的相互作用通常引发低聚/聚合反应。在这些杂芳烃与路易斯酸的反应中也观察到类似的行为。当路易斯酸通过质子化被激活时会产生特殊效果。氘代布朗斯特酸可直接对富电子杂芳烃进行氘代。汞盐作为极弱的路易斯酸可直接进行金属化反应,以直接的方式取代环上的氢原子,生成有机汞杂环。这篇综述将提供有关此类杂环与布朗斯特酸和路易斯酸加合物化学的全面信息,使化学家能够理解该领域的机理和潜力,并将这些发现应用于未来的合成中。

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