Use of metastable, dissociated and charged gas species in synthesis: a low pressure analogue of the high pressure technique

Abstract

Oxidation of silver using microwave-induced oxygen plasma and oxygen-ozone gas mixture was studied as a function of temperature and partial pressure. The oxide Ag₂O was formed at temperatures well above its normal decomposition temperature in oxygen plasma at a pressure of 5 Pa. The higher oxide AgO_1−x was formed in O₂+O₃ gas mixtures at lower temperatures. The oxygen chemical potentials for the oxidation of Ag to Ag₂O, Ag₂O to AgO_1−x and AgO to Ag₂O₃ were evaluated from thermodynamic data and compared with the experimental results to obtain information on the chemical potential of oxygen in microwave plasma and gases containing ozone. The oxygen potential of the gas phase in microwave plasma operating at a pressure of 5 Pa was found to be in excess of 36 kJ/mol at 750 K. This is equivalent to a pressure of diatomic oxygen gas greater than 3 × 10⁷ Pa. In the O₂+O₃ mixture at ambient pressure containing 5 mole percent O₃, the oxygen potential is ∼112 kJ/mol at 465 K. The equivalent pressure of diatomic oxygen is ∼4 × 10¹⁷ Pa. Thus, metastable species such as O₃ or charged species such as O⁻ present in plasma can be used as a powerful reagent for the syntheses of metastable oxides. Similar techniques can be used for other metastable inorganic solids such as nitrides for functional applications.