Formation of nitroxide radicals from secondary amines and peracids: A peroxyl radical oxidation pathway derived from electron spin resonance detection and density functional theory calculation

By electron spin resonance (ESR) detection and quantum chemical calculation based on the density functional theory (DFT) at the B3LYP/6-31G(d) level, we found that the formation of nitroxide radicals from secondary amines and peracids is a peroxyl radical oxidation reaction, where peroxyl radicals are the reactive intermediates of peracids in the oxidation. The DFT calculation revealed the transition structures and activation barriers of oxidizing pyrrolidine by the peroxyl radicals of peracetic acid and percarboximidic acid. Their barriers are 11.75 and 12.35 kcal/mol, respectively, showing that the peroxyl radicals have high reactivity on secondary amines. A reaction path calculation (IRC) of the oxidation of pyrrolidine by the peroxyl radical of percarboximidic acid illustrated the process of the formation of nitroxide radical: firstly, the terminal oxygen atom of the peroxyl radical R{single bond}O{single bond}O{radical dot} attacks the nitrogen atom of secondary amine and forms a N{single bond}O bond, and then the hydrogen atom from the N{single bond}H of the secondary amine is transferred to the imido nitrogen atom or the carbonyl oxygen atom of peracid and finally forms a new N{single bond}H or O{single bond}H bond.