Efficient synthesis of esters through oxone-catalyzed dehydrogenation of carboxylic acids and alcohols

Hou, Fei; Wang, Xi Cun; Quan, Zheng‐Jun

doi:10.1039/c8ob02539h

Cited by 15 publications

(3 citation statements)

References 75 publications

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“…reported an efficient synthesis of esters 713 a – x through oxone‐mediated esterification of carboxylic acids 712 with alcohols under mild reaction condition (Scheme 216). [486] The reaction was found to be compatible with both electron‐rich as well as electron‐poor groups and the gram‐scale synthesis was also fruitfully accomplished by the authors. A plausible mechanism for this reaction involving path A and path B is detailed in the Scheme 217.…”

Section: Miscellaneous Reactionsmentioning

confidence: 91%

Applications of Oxone® in Organic Synthesis: An Emerging Green Reagent of Modern Era

2022

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Presently, the major cornerstone of the research community is to develop green as well as sustainable protocols involving inexpensive catalysts and/or reagents without the usage of hazardous solvents under globally friendlier conditions in order to shelter both mankind and environment. Therefore, needless to say, there is always a supreme need to surrogate the older, costlier and unsafe strategies with the novel economically inexpensive and environmental benign ones. To this context, in recent past, oxone® (triple salt), a very cheap oxidizing agent having the chemical formula 2KHSO5 ⋅ KHSO4 ⋅ K2SO4 and enwrapped with the unique characteristics like easy handling, non‐toxic, safe, eco‐friendly, non‐polluting, stable, and nicely soluble in water, in addition to its utility for large‐scale synthesis etc. Bearing the importance of this versatile reagent in mind, we envisioned to update the recent advances made in this direction. Consequently, in this particular review article, the developments made in the arena of oxone chemistry covering from 2013 to 2020 have been revealed as no report appeared in the literature after a wonderful Chem. Rev. published by the group of Hussain in 2013. Herein, a comprehensive detail of a variety of oxidative transformations along with the complete plausible mechanistic steps have been exposed. For sure, present review would be a very helpful tool to the scientific community not only working in the area of organic synthesis but also to the researchers working in other branches of science and technologies as well.

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Section: Miscellaneous Reactionsmentioning

confidence: 91%

Applications of Oxone® in Organic Synthesis: An Emerging Green Reagent of Modern Era

2022

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“…Employing methanol ( 2a ), ethanol ( 2b ) or n -propanol ( 2c ) as both a nucleophilic coupling partner and solvent, the alcoholysis transformation furnished the desired products in satisfactory outcomes under electrochemical conditions. Although moderate to good yields were obtained for other alcohols in this electrochemical alcoholysis transformation, there were three principal changes that should be noted: firstly, the gradually decreased yields for the conversion reflected the decay of nucleophilicity caused by the increased steric hindrance of the alcohol substrates, 20 especially for the relatively high steric hindrance of alcohol substrates ( 2d–j ), and therefore electrochemical alcoholysis transformation needed to be carried out under inert nitrogen conditions to suppress possible side reactions including homocoupling of alkoxysilanes or hydrolysis of silane with H 2 O in air; secondly, the increased carbon chain length of alcohol substrates ( 2e–j ) resulted in diminished solubility for the reaction mixtures; hence anhydrous CH 3 CN/ROH (5 : 0.1) mixed solvents were employed as solvents instead of alcohols alone to promote the solubility and conductivity of the reaction system; thirdly, the generation of the disiloxane byproduct hexaphenyldisiloxane rather than the desired alcoholysis product was observed for NaBr-mediated alcoholysis of triphenylsilane in anhydrous CH 3 CN/ t -amyl alcohol ( 2j ) mixed solvents under inert nitrogen conditions. Considering that TBAB is a good redox mediator for some electrochemical conversion, 18 TBAB was used instead of NaBr as the mediator and electrolyte for the electrochemical alcoholysis transformation between triphenylsilane and t -amyl alcohol ( 2j ).…”

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confidence: 94%

Electrochemical strategies for NaX-mediated hydrolysis and alcoholysis of hydrosilanes under mild conditions

Fu,

Xiao,

Yin

et al. 2024

Green Chem.

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“…Ester compounds are one of the most important raw materials in chemical industry and organic synthesis and constitute numerous artificial fragrances, flavoring agents, solvent extractants and chemical intermediates [1]. The traditional synthetic method for preparation of esters involves a two-step procedure, including the oxidation of aldehyde and/or alcohol and the subsequent esterification between carboxylic acid and its activated derivatives with alcohols [2][3][4]. The multistep process involves the production of large amounts of toxic wastes and irremovable byproducts, which is not conducive to the development of green chemistry.…”

Section: Introductionmentioning

confidence: 99%

Zn Promoted Mg-Al Mixed Oxides-Supported Gold Nanoclusters for Direct Oxidative Esterification of Aldehyde to Ester

Wang

et al. 2021

IJMS

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The synthesis of ester compounds is one of the most important chemical processes. In this work, Zn-Mg-Al mixed oxides with different Zn2+/Mg2+ molar ratios were prepared via co-precipitation method and supported gold nanoclusters to study the direct oxidative esterification of aldehyde and alcohol in the presence of molecular oxygen. Various characterization techniques such as N2-physical adsorption, X-ray diffraction (XRD), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS) and CO2 temperature programmed desorption (TPD) were utilized to analyze the structural and electronic properties. Based on the results, the presence of small amounts of Zn2+ ions (~5 wt.%) provoked a remarkable modification of the binary Mg-Al system, which enhanced the interaction between gold with the support and reduced the particle size of gold. For oxidative esterification reaction, the Au25/Zn0.05MgAl-400 catalyst showed the best performance, with the highest turnover frequency (TOF) of 1933 h−1. The active center was believed to be located at the interface between metallic gold with the support, where basic sites contribute a lot to transformation of the substrate.

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Efficient synthesis of esters through oxone-catalyzed dehydrogenation of carboxylic acids and alcohols

Abstract: An environmentally friendly oxone (20 mol%) catalyzed esterification of carboxylic acids with alcohols has been developed, providing an attractive alternative to the construction of valuable carbonyl esters.

Cited by 15 publications

References 75 publications

Applications of Oxone® in Organic Synthesis: An Emerging Green Reagent of Modern Era

Applications of Oxone® in Organic Synthesis: An Emerging Green Reagent of Modern Era

Electrochemical strategies for NaX-mediated hydrolysis and alcoholysis of hydrosilanes under mild conditions

Zn Promoted Mg-Al Mixed Oxides-Supported Gold Nanoclusters for Direct Oxidative Esterification of Aldehyde to Ester

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