高效合成β-烯胺酮的同时不同机制:以纳米二氧化硅为载体的 12-钨钴酸作为电子传递和勃氏酸纳米催化剂

Mahtab Razlansari, Masoud Kahrizi
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引用次数: 0

摘要

本研究将 12-钨钴酸 H5CoW12O40 固定在稻壳纳米二氧化硅(CoW@NSiO2)上,开发出一种新型、高效、异构和可回收的纳米催化剂,用于合成 β-烯氨基酮。酸度和循环伏安测量结果表明,该催化剂具有电活性,能发生可逆的氧化还原转变,并且含有强酸位点和移动质子。机理研究表明,CoW@NSiO2 可通过电子转移和布氏酸机理两种途径同时催化 β-烯丙酮的合成。为了证实电子转移和酸性机理同时催化合成烯丙基酰胺酮,在 K5Co 作为电活性催化剂和 CoW@NSiO2 与电子清除剂作为酸性催化剂存在的条件下进行了模型反应。结果表明,反应通过两种机制同时进行。有证据表明,这种催化剂的电子转移特性在这类有机反应中最为明显。该催化剂表现出卓越的性能,而且该方法被证明是通用的,可在多种基质中产生优异的结果。值得一提的是,脂肪族胺在该工艺中具有良好的耐受性,并能以优异的产率和较短的反应时间生成 β-烯丙酮化合物。此外,与环状 1,3-二酮(dimedone)的反应也能产生中等产率的产品。此外,该催化剂还表现出显著的可回收性,可在至少连续五个循环中保持活性,而不会出现任何明显的衰退。值得注意的是,循环伏安法和酸度测量显示,催化剂的电子转移特性和布氏酸度在五次运行后保持不变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Simultaneous different mechanisms for the efficient synthesis of β-enaminones: 12-tungstocobaltic acid-supported on nano silica as an electron transfer and Brønsted acid nano catalyst
In the present study, 12-tungestocobaltic acid, H5CoW12O40, was immobilized on nano silica from rice husk (CoW@NSiO2) to develop a novel, efficient, heterogeneous and recyclable nano catalyst for the synthesis of β-enaminones. It is apparent from acidity and cyclic voltammetric measurements that, the catalyst is electroactive and undergoes reversible redox transitions, as well as it is contains strong acid sites and mobile protons. As evidenced from mechanistic investigations, CoW@NSiO2 can catalyze the synthesis of β-enaminones with two simultaneous ways: electron transfer and Brønsted acid mechanisms. In order to confirm the synthesis of enaminones through simultaneous mechanisms of electron transfer and acidity, the model reaction was carried out in the presence of K5Co as an electroactive catalyst and CoW@NSiO2 with electron scavenger as an acid catalyst. The results showed that the reaction proceeded simultaneously through both mechanisms. There is evidence that the electron transfer property of this catalyst is most pronounced in this type of organic reactions. The catalyst demonstrated outstanding performance, and the methodology proved to be versatile, yielding excellent results across a wide range of substrates. It is worth mentioning that aliphatic amines were well-tolerated in the process and produced β-enaminone compounds with excellent yields and short reaction times. Also, reactions with dimedone, a cyclic 1,3-diketone, delivered moderate product yields. Additionally, the catalyst showed remarkable recyclability, maintaining its activity for a minimum of five consecutive cycles without any noticeable decline. Notably, the cyclic voltammetric and acidity measurements revealed that the catalyst’s electron transfer property and Brønsted acidity remained unchanged after five runs.
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