ABSTRACT The oxidation of phosphine (PH 3 ) plays an important role in the photochemical phosphorus‐hydrogen‐oxygen network of the Earth's atmosphere. The phosphinyl radical (•PH 2 ) is a key intermediate in the photochemistry of PH 3 , and its reactions with O 2 yield phosphorus oxyacids as stable reservoirs via the intermediacy of yet elusive radicals. Herein, we report the identification of the simplest phosphinylperoxy radical H 2 POO• in gas phase reaction between •PH 2 and O 2 . The characterization of H 2 POO• with matrix‐isolation IR and UV‐vis spectroscopy is supported by D‐ and 18 O‐isotope labeling experiments and quantum chemical calculations. Upon photoexcitation at 410 nm, the matrix‐isolated H 2 POO• undergoes successive hydrogen‐migration to form two isomers HP(O)OH• and •P(OH) 2 . Further UV‐irradiation at 365 nm causes decomposition to yield the water complex of phosphorus monoxide (•PO), which can be photolytically converted to metaphosphorous acid (HOPO). The disclosed photochemistry of these novel phosphorus‐bearing molecules helps in understanding the photochemical network of PH 3 in the atmospheric and interstellar phosphorus chemistry.
Jiang et al. (Fri,) studied this question.