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Fysik & material 7.3 🇷🇺 🇸🇪

Chemists finally capture elusive molecular intermediates that explain decades of oxidation reactions

Researchers have directly observed tetroxide molecules—fleeting intermediates that form when organic peroxy radicals react—vindicating a mechanism proposed in 1957 but never clearly seen until now. The finding clarifies fundamental chemistry underlying industrial oxidation processes, environmental pollutant formation, and emerging cancer treatments.

Originaltitel: Observing elusive tetroxides in gas-phase radical reactions supports the Russell mechanism

Abstrakt

Organic peroxy radicals (RO 2 ) are important intermediates for oxidation processes in aerobic chemical systems. Their self- and “cross”-reactions (i.e., with themselves and other RO 2 ) are increasingly receiving attention in a wide range of applications, from atmospheric chemistry to cancer therapies. However, their mechanism has been debated for decades. The Russell mechanism, widely assumed for these reactions today, is characterized by a tetroxide intermediate, only observed once and partially since its postulate in 1957. Here we report the observation of tetroxides in the gas-phase reactions of different RO 2 by direct mass spectrometry, in which ionic and gas-phase dimerization could be ruled out. Within the uncertainties in the kinetic profiles, the lifetime for CH 3 OOOOCH 3 was determined to be in the range 0.2 and 200 milliseconds, consistent with an intermediate and supporting the Russell mechanism.

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