Borate-assisted liquid-phase selective oxidation of n-pentane

Aworinde, Samson M.; Wang, Kun; Lapkin, Alexei A.

doi:10.1016/j.apcata.2018.06.023

Cited by 6 publications

(2 citation statements)

References 40 publications

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“…Orthoboric acid esters were prepared in situ in the synthesis of secondary alcohols by oxidation of paraffi nic hydrocarbons according to the Bashkirov procedure to avoid their further oxidation. [90][91][92][93] The reactivity of the cyclohexyl moiety in the boric acid ester is lower than in cyclohexanol, but somewhat higher than in cyclohexyl acetate (see Table 2). 84…”

Section: Methodsmentioning

confidence: 99%

The specific features of the liquid-phase oxidation of saturated esters. Kinetics, reactivity and mechanisms of formation of destruction products

Perkel

Voronina

2020

Russ Chem Bull

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Data on kinetics, reactivity, and mechanisms of formation of destruction products of the liquid-phase oxidation of saturated esters by molecular oxygen have been systematized and discussed. The ester group has both an activating and deactivating eff ects on the reactivity of the СН bonds of the alkoxyl (α´-, β´-, γ´-, and δ´-) and acyl (α-, β-, and γ-) groups. The activating eff ect in esters is weaker than in alcohols, ketones, and ethers and extends to the αand α´-CH bonds. The reactivity of the β-, β´-, and γ´-СН bonds is signifi cantly lower than that of the secondary СН bonds of hydrocarbons. Oxidation of the β-СН bonds of the acyl moieties of esters leads to НОО • radical, α,β-epoxy-, α,β-dihydroxy-, and α,β-unsaturated esters, but not to hydroperoxides. Upon the oxidation of esters, the highly active α-carboxyalkylperoxy-, α-acyloxyperoxy-, and НОО • -radicals are formed. The recombination reactions involving these radicals occur both with and without chain termination. The specifi city of the decomposition of ester hydroperoxides are due to intra-and intermolecular interactions of the hydroperoxide groups with the ester groups. Labile peroxide intermediates (α-hydroxyperoxyesters, peroxyesters, and peroxylactones) are formed through the corresponding tetrahedral intermediates and decay predominantly by the non-radical pathway. The recombination of the peroxyl radicals and the decay of labile peroxides result in the parallel accumulation of per oxide and non-peroxide products during the oxidation of esters.

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Section: Methodsmentioning

confidence: 99%

The specific features of the liquid-phase oxidation of saturated esters. Kinetics, reactivity and mechanisms of formation of destruction products

Perkel

Voronina

2020

Russ Chem Bull

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“…The internal packing of the reactor is an efficient radical scavenger, whereas the micro-heat exchanger has previously been shown to be highly efficient in elevated temperature selective oxidation reactions (Bavykin et al, 2005). We hypothesised that the addition of a radical initiator may enhance the reaction rate, especially at short residence times; this is based on our previous work on aerobic oxidation in the liquid phase (Aworinde et al, 2018).…”

Section: Optimisation Of the Radical Dehydrogenation Reactionmentioning

confidence: 99%