Cathodoluminescence of iron oxides and oxyhydroxides

Abstract

Abstract Iron oxides and oxyhydroxides show promise as superconductor materials and as repositories of paleo-environmental information. However, there are no microscale non-destructive analytical techniques to characterize their combined mineralogy, chemical composition, and crystal properties. We address this by developing cathodoluminescence mounted on a scanning electron microscope (SEM-CL) as an in situ, non-destructive method for the crystallographic and petrographic study of iron oxides and oxyhydroxides. We show that goethite, hematite, and magnetite display different SEM-CL spectra, which may be used for mineral identification. We further show that different formation pH, manganese substitution for iron in goethite and hematite, and titanium substitution for iron in magnetite cause shifts in the SEM-CL spectra of these minerals. These spectral shifts are not always detectable as a change in the emission color but are easily discernable by quantitative analysis of the spectra. Together with subtle but observable variations in the SEM-CL spectra of natural goethite and hematite, we suggest that these dependences of the SEM-CL spectra on pH and chemical composition may be used as a means of identifying multiple episodes of mineralization and recrystallization. We apply the newly developed SEM-CL methods to two polished sections of natural samples and show that quantitative analysis of the spectra obtained allows the identification of differences between varieties of the same mineral that are not observable by other means. Like the application of SEM-CL to geologic samples in this study, we suggest that this approach may be used to explore the in situ chemistry and crystallinity of various natural and manufactured iron oxides and oxyhydroxides.