Microstructural and chemical effects in Al2O3 implanted with iron at room temperature and annealed in oxidizing or reducing atmospheres

Abstract

Rutherford backscattering (RBS)-ion channeling, transmission electron microscopy (TEM), and conversion electron Mössbauer spectroscopy (CEMS) have been used to determine the structure of α–Al₂O₃ implanted with iron at room temperature. Changes produced by post-implantation annealing in oxidizing and reducing atmospheres were followed using the same techniques. Implantation of 160 keV Fe at room temperature produces a damaged but crystalline microstructure for fluences as high as 1 × 10¹⁷ Fe/cm². The iron resides in a variety of local environments: three Fe²⁺ components, one Fe⁰ component, and two Fe⁴⁺ components. The relative amount of each component varies with implantation fluence. Only the Fe⁰ component seems to be associated with second-phase formation. In this case, 2 nm diameter α-iron particles were detected by TEM studies. Recovery of implantation-induced disorder in the Al- and oxygen-sublattices occurs in two stages for annealing in oxygen and in one continuous stage for hydrogen-annealing. The end state for iron is Fe³⁺ for oxygen anneals and Fe⁰ for hydrogen anneals. The precipitated phases observed are those to be expected from the equilibrium phase diagrams.