Singlet oxygen (1O2) generation through simple disproportionation of H2O2 is one of the cleanest, safest, and most easily accessible means of achieving a potent oxidizing action that can be exploited for a wide range of applications, from antimicrobial surfaces to many heterogeneous chemical transformations. However, most catalysts known to date for this reaction operate under highly alkaline conditions and lose potency under neutral conditions. This study reports the discovery of a new class of oxide catalysts with high electron affinity and work function, namely, LaSrMnO3, La2NiO4, δ-MnO2, and V2O5, which have high efficiency for H2O2 disproportionation into 1O2 without the production of the *OH radical under circumneutral pH conditions. Studies of these oxides with a wide range of oxygen vacancy (VO) defects as potential catalytic sites for H2O2 disproportionation show that VO defects quenches the catalytic activity in V2O5, which is shown to be due to the electronic effect where increasing VO defects leads to an increased Burstein–Moss (B-M) shift of Fermi energy well into the conduction band (CB), making injection of e– from H2O2 unfavorable. The increasing presence of MnIII defects in manganites enhances 1O2 production due to increased work function. The study provides a roadmap for the engineering of powerful 1O2 generators for use as selective oxidative catalysts.
Mangu et al. (Fri,) studied this question.