Lindie Marais scite author profile

Herein a bis(pyridyl)-N-alkylamine/Cu/TEMPO/NMI catalyst system is reported for aerobic oxidation of a variety of primary alcohols to the corresponding aldehydes using readily available reagents, at room temperature and ambient air as the oxidant. ESI-MS analysis of the reaction showed the formation of a [(L1)(NMI)Cu-OOH] species, which is a key intermediate in the alcohol oxidation reaction. Evaluation of the effect of reaction parameters on the initial rate of the reaction allowed us to obtain the optimum conditions for catalytic activity. The careful choice of reaction solvent allowed for the oxidation of 4-hydroxybenzyl alcohol, a substrate which proved problematic in previous studies. In the case of 2-pyridinemethanol as substrate, experimental evidence shows that catalytic activity is diminished due to competitive inhibition of the catalyst by the alcohol substrate.

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Biomimetic Cu/Nitroxyl Catalyst Systems for Selective Alcohol Oxidation

Marais

Swarts

2019

Catalysts

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The oxidation of alcohols to the corresponding carbonyl products is an important organic transformation and the products are used in a variety of applications. The development of catalytic methods for selective alcohol oxidation have garnered significant attention in an attempt to find a more sustainable method without any limitations. Copper, in combination with 2,2,6,6-tetramethyl-1-piperidine N-oxyl (TEMPO) and supported by organic ligands, have emerged as the most effective catalysts for selective alcohol oxidation and these catalyst systems are frequently compared to galactose oxidase (GOase). The efficiency of GOase has led to extensive research to mimic the active sites of these enzymes, leading to a variety of Cu/TEMPO· catalyst systems being reported over the years. The mechanistic pathway by which Cu/TEMPO· catalyst systems operate has been investigated by several research groups, which led to partially contradicting mechanistic description. Due to the disadvantages and limitations of employing TEMPO· as co-catalyst, alternative nitroxyl radicals or in situ formed radicals, as co-catalysts, have been successfully evaluated in alcohol oxidation. Herein we discuss the development and mechanistic elucidation of Cu/TEMPO· catalyst systems as biomimetic alcohol oxidation catalysts.

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The development of a Cu(I)/pyrazolylpyridineamine catalyst system for the hydroxylation of aryl halides

Marais

Vosloo

Swarts

2020

Molecular Catalysis

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The development of a Cu(I)/Bis(pyridyl)-N-alkylamine catalyst system for selective alcohol oxidation

Marais

Burés

Jordaan

et al. 2017

Suid-Afrikaanse Tydskr Natuurwetenskap Tegnol

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Lindie Marais

Homogeneous oxidative transformations mediated by copper catalyst systems

A bis(pyridyl)-N-alkylamine/Cu(i) catalyst system for aerobic alcohol oxidation

Biomimetic Cu/Nitroxyl Catalyst Systems for Selective Alcohol Oxidation

The development of a Cu(I)/pyrazolylpyridineamine catalyst system for the hydroxylation of aryl halides

The development of a Cu(I)/Bis(pyridyl)-N-alkylamine catalyst system for selective alcohol oxidation

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