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

Abstract: 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… Show more

“…The lifetime of RO 2 radicals can be very difficult to gauge as they undergo multiple reaction pathways. , Despite the complexity associated with RO 2 radicals, ,, we believe that the decreasing trend in the γ of m / z 223 (Figure D) can be attributed to pathway 1d in Scheme . It is our understanding that, at enhanced precursor concentrations, the RO 2 radicals can form unstable oxygenated intermediates (e.g., tetroxides), , which are highly likely to decompose to alcohols and carbonyls. While additional decomposition products such as ROOR can be expected, it would be possible at even higher precursor concentrations (>10 mM), which are irrelevant to cloud water conditions.…”

“…72,99 Despite the complexity associated with RO 2 radicals, 1,96,99 we believe that the decreasing trend in the γ of m/z 223 (Figure 4D) can be attributed to pathway 1d in Scheme 1. It is our understanding that, at enhanced precursor concentrations, the RO 2 radicals can form unstable oxygenated intermediates (e.g., tetroxides), 72,99 which are highly likely to decompose to alcohols and carbonyls. While additional decomposition products such as ROOR can be expected, 1 it would be possible at even higher precursor concentrations (>10 mM), which are irrelevant to Based on the above observations, we hypothesize that the γ of aqueous ROOHs can be suppressed by increasing oxidant and precursor concentrations.…”

Photooxidation-Initiated Aqueous-Phase Formation of Organic Peroxides: Delving into Formation Mechanisms

“…The lifetime of RO 2 radicals can be very difficult to gauge as they undergo multiple reaction pathways. , Despite the complexity associated with RO 2 radicals, ,, we believe that the decreasing trend in the γ of m / z 223 (Figure D) can be attributed to pathway 1d in Scheme . It is our understanding that, at enhanced precursor concentrations, the RO 2 radicals can form unstable oxygenated intermediates (e.g., tetroxides), , which are highly likely to decompose to alcohols and carbonyls. While additional decomposition products such as ROOR can be expected, it would be possible at even higher precursor concentrations (>10 mM), which are irrelevant to cloud water conditions.…”

“…72,99 Despite the complexity associated with RO 2 radicals, 1,96,99 we believe that the decreasing trend in the γ of m/z 223 (Figure 4D) can be attributed to pathway 1d in Scheme 1. It is our understanding that, at enhanced precursor concentrations, the RO 2 radicals can form unstable oxygenated intermediates (e.g., tetroxides), 72,99 which are highly likely to decompose to alcohols and carbonyls. While additional decomposition products such as ROOR can be expected, 1 it would be possible at even higher precursor concentrations (>10 mM), which are irrelevant to Based on the above observations, we hypothesize that the γ of aqueous ROOHs can be suppressed by increasing oxidant and precursor concentrations.…”

Photooxidation-Initiated Aqueous-Phase Formation of Organic Peroxides: Delving into Formation Mechanisms

“…The lifetime of RO 2 radicals can be very difficult to gauge due to undergoing multiple reaction pathways. 58,82 Despite the complexity associated with RO 2 radicals, 79,82,83 we believe that the decreasing trend in the γ of m/z 223 (Figure 4 (C)) can be attributed to pathway 1d in Scheme 1. It is our understanding that at enhanced precursor concentrations, the RO 2 radicals can form unstable oxygenated intermediates (e.g., tetroxides), 58,82 which are highly likely to decompose to alcohols and carbonyls.…”

“…58,82 Despite the complexity associated with RO 2 radicals, 79,82,83 we believe that the decreasing trend in the γ of m/z 223 (Figure 4 (C)) can be attributed to pathway 1d in Scheme 1. It is our understanding that at enhanced precursor concentrations, the RO 2 radicals can form unstable oxygenated intermediates (e.g., tetroxides), 58,82 which are highly likely to decompose to alcohols and carbonyls. While additional decomposition products such as ROOR can be expected, 83 it would be possible at even higher precursor concentrations (>10 mM), which are currently beyond the scope of this study.…”

Aqueous-phase autoxidation in the atmosphere: fate and formation of organic peroxides

Kinetic patterns for thermal oxidation of binary and ternary blends based on polylactide and polyethylene